Identification, monitoring and treatment of disease and characterization of biological condition using gene expression profiles

ABSTRACT

A method provides an index that is indicative of the state of a subject, as to a biological condition, based on a sample from the subject. An embodiment of this method includes: deriving from the sample a profile data set, the profile data set including a plurality of members, each member being a quantitative measure of the amount of a distinct RNA or protein constituent in a panel of constituents selected so that measurement of the constituents enables evaluation of the biological condition; and in deriving the profile data set, achieving such measure for each constituent under measurement conditions that are substantially repeatable; and applying values from the profile data set to an index function that provides a mapping from an instance of a profile data set into a single-valued measure of biological condition, so as to produce an index pertinent to the biological condition of the subject.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 12/609,578, filed Oct. 30, 2009 now U.S. Pat. No. 8,055,452; which is a continuation of U.S. application Ser. No. 11/158,504, filed Jun. 22, 2005 now abandoned; which is a continuation of U.S. application Ser. No. 10/291,856, filed Nov. 8, 2002 now U.S. Pat. No. 6,964,850; which claims priority to U.S. provisional application No. 60/348,213, filed Nov. 9, 2001; U.S. provisional application No. 60/340,881, filed Dec. 7, 2001; U.S. provisional application No. 60/369,633, filed Apr. 3, 2002; and U.S. provisional application No. 60/376,997, filed Apr. 30, 2002; which disclosures are herein incorporated by reference in their entirety.

TECHNICAL FIELD AND BACKGROUND ART

The present invention relates to use of gene expression data, and in particular to use of gene expression data in identification, monitoring and treatment of disease and in characterization of biological condition of a subject.

The prior art has utilized gene expression data to determine the presence or absence of particular markers as diagnostic of a particular condition, and in some circumstances have described the cumulative addition of scores for over expression of particular disease markers to achieve increased accuracy or sensitivity of diagnosis. Information on any condition of a particular patient and a patient's response to types and dosages of therapeutic or nutritional agents has become an important issue in clinical medicine today not only from the aspect of efficiency of medical practice for the health care industry but for improved outcomes and benefits for the patients.

SUMMARY OF THE INVENTION

In a first embodiment, there is provided a method, for evaluating a biological condition of a subject, based on a sample from the subject. The method includes: deriving from the sample a profile data set, the profile data set including a plurality of members, each member being a quantitative measure of the amount of a distinct RNA or

-   -   protein constituent in a panel of constituents selected so that         measurement of the constituents enables evaluation of the         biological condition; and     -   in deriving the profile data set, achieving such measure for         each constituent under measurement conditions that are         substantially repeatable.

There is a related embodiment for providing an index that is indicative of the state of a subject, as to a biological condition, based on a sample from the subject. This embodiment includes:

-   -   deriving from the sample a profile data set, the profile data         set including a plurality of members, each member being a         quantitative measure of the amount of a distinct RNA or protein         constituent in a panel of constituents selected so that         measurement of the constituents enables evaluation of the         biological condition; and     -   in deriving the profile data set, achieving such measure for         each constituent under measurement conditions that are         substantially repeatable; and     -   applying values from the profile data set to an index function         that provides a mapping from an instance of a profile data set         into a single-valued measure of biological condition, so as to         produce an index pertinent to the biological condition of the         subject.

In further embodiments related to the foregoing, there is also included, in deriving the profile data set, achieving such measure for each constituent under measurement conditions wherein specificity and efficiencies of amplification for all constituents are substantially similar. Similarly further embodiments include alternatively or in addition, in deriving the profile data set, achieving such measure for each constituent under measurement conditions wherein specificity and efficiencies of amplification for all constituents are substantially similar.

In embodiments relating to providing the index a further embodiment also includes providing with the index a normative value of the index function, determined with respect to a relevant population, so that the index may be interpreted in relation to the normative value. Optionally providing the normative value includes constructing the index function so that the normative value is approximately 1. Also optionally, the relevant population has in common a property that is at least one of age group, gender, ethnicity, geographic location, diet, medical disorder, clinical indicator, medication, physical activity, body mass, and environmental exposure.

In another related embodiment, efficiencies of amplification, expressed as a percent, for all constituents lie within a range of approximately 2 percent, and optionally, approximately 1 percent.

In another related embodiment, measurement conditions are repeatable so that such measure for each constituent has a coefficient of variation, on repeated derivation of such measure from the sample, that is less than approximately 3 percent. In further embodiments, the panel includes at least three constituents and optionally fewer than approximately 500 constituents.

In another embodiment, the biological condition being evaluated is with respect to a localized tissue of the subject and the sample is derived from tissue or fluid of a type distinct from that of the localized tissue.

In related embodiments, the biological condition may be any of the conditions identified in Tables 1 through 12 herein, in which case there are measurements conducted corresponding to constituents of the corresponding Gene Expression Panel. The panel in each case includes at least two, and optionally at least three, four, five, six, seven, eight, nine or ten, of the constituents of the corresponding Gene Expression Panel.

In another embodiment, there is provided a method of providing an index that is indicative of the inflammatory state of a subject based on a sample from the subject that includes: deriving from the sample a first profile data set, the first profile data set including a plurality of members, each member being a quantitative measure of the amount of a distinct RNA or protein constituent in a panel of constituents, the panel including at least two of the constituents of the Inflammation Gene Expression Panel of Table 1; (although in other embodiments, at least three, four, five, six or ten constituents of the panel of Table 1 may be used in a panel) wherein, in deriving the first profile data set, such measure is performed for each constituent both under conditions wherein specificity and efficiencies of amplification for all constituents are substantially similar and under substantially repeatable conditions; and applying values from the first profile data set to an index function that provides a mapping from an instance of a profile data set into a single-valued measure of biological condition (in an embodiment, this may be an inflammatory condition), so as to produce an index pertinent to the biological condition of the sample or the subject. The biological condition may be any condition that is assessable using an appropriate Gene Expression Panel; the measurement of the extent of inflammation using the Inflammation Gene Expression Panel is merely an example.

In additional embodiments, the mapping by the index function may be further based on an instance of a relevant baseline profile data set and values may be applied from a corresponding baseline profile data set from the same subject or from a population of subjects or samples with a similar or different biological condition. Additionally, the index function may be constructed to deviate from a normative value generally upwardly in an instance of an increase in expression of a constituent whose increase is associated with an increase of inflammation and also in an instance of a decrease in expression of a constituent whose decrease is associated with an increase of inflammation. The index function alternatively be constructed to weigh the expression value of a constituent in the panel generally in accordance with the extent to which its expression level is determined to be correlated with extent of inflammation. The index function may be alternatively constructed to take into account clinical insight into inflammation biology or to take into account experimentally derived data or to take into account relationships derived from computer analysis of profile data sets in a data base associating profile data sets with clinical and demographic data. In this connection, the construction of the index function may be achieved using statistical methods, which evaluate such data, to establish a model of constituent expression values that is an optimized predictor of extent of inflammation.

In another embodiment, the panel includes at least one constituent that is associated with a specific inflammatory disease.

The methods described above may further utilize the step wherein (i) the mapping by the index function is also based on an instance of at least one of demographic data and clinical data and (ii) values are applied from the first profile data set including applying a set of values associated with at least one of demographic data and clinical data.

In another embodiment of the above methods, a portion of deriving the first profile data set is performed at a first location and applying the values from the first profile data set is performed at a second location, and data associated with performing the portion of deriving the first profile data set are communicated to the second location over a network to enable, at the second location, applying the values from the first profile data set.

In an embodiment of the methods, the index function is a linear sum of terms, each term being a contribution function of a member of the profile data set. Moreover, the contribution function may be a weighted sum of powers of one of the member or its reciprocal, and the powers may be integral, so that the contribution function is a polynomial of one of the member or its reciprocal. Optionally, the polynomial is a linear polynomial. The profile data set may include at least three, four or all members corresponding to constituents selected from the group consisting of IL1A, IL1B, TNF, IFNG and IL10. The index function may be proportional to ¼{IL1A}+¼{IL1B}+¼{TNF}+¼{INFG}−1/{IL10} and braces around a constituent designate measurement of such constituent.

In an additional embodiment, a method is provided of analyzing complex data associated with a sample from a subject for information pertinent to inflammation, the method that includes: deriving a Gene Expression Profile for the sample, the Gene Expression Profile being based on a Signature Panel for Inflammation; and using the Gene Expression Profile to determine a Gene Expression Profile Inflammatory Index for the sample.

In an additional embodiment, a method is provided of monitoring the biological condition of a subject, that includes deriving a Gene Expression Profile for each of a series of samples over time from the subject, the Gene Expression Profile being based on a Signature Panel for Inflammation; and for each of the series of samples, using the corresponding Gene Expression Profile to determine a Gene Expression Profile Inflammatory Index.

In an additional embodiment, there is provided a method of determining at least one of (i) an effective dose of an agent to be administered to a subject and (ii) a schedule for administration of an agent to a subject, the method including: deriving a Gene Expression Profile for a sample from the subject, the Gene Expression Profile being based on a Signature Panel for Inflammation; using the Gene Expression Profile to determine a Gene Expression Profile Inflammatory Index for the sample; and

-   -   using the Gene Expression Profile Inflammatory Index as an         indicator in establishing at least one of the effective dose and         the schedule.

In an additional embodiment, a method of guiding a decision to continue or modify therapy for a biological condition of a subject, is provided that includes: deriving a Gene Expression Profile for a sample from the subject, the Gene Expression Profile being based on a Signature Panel for Inflammation; and using the Gene Expression Profile to determine a Gene Expression Profile Inflammatory Index for the sample.

A method of predicting change in biological condition of a subject as a result of exposure to an agent, is provided that includes: deriving a first Gene Expression Profile for a first sample from the subject in the absence of the agent, the first Gene Expression Profile being based on a Signature Panel for Inflammation; deriving a second Gene Expression Profile for a second sample from the subject in the presence of the agent, the second Gene Expression Profile being based on the same Signature Panel; and using the first and second Gene Expression Profiles to determine correspondingly a first Gene Expression Profile Inflammatory Index and a second Gene Expression Profile Inflammatory Index. Accordingly, the agent may be a compound and the compound may be therapeutic.

In an additional embodiment, a method of evaluating a property of an agent is provided where the property is at least one of purity, potency, quality, efficacy or safety, the method including: deriving a first Gene Expression Profile from a sample reflecting exposure to the agent of (i) the sample, or (ii) a population of cells from which the sample is derived, or (iii) a subject from which the sample is derived; using the Gene Expression Profile to determine a Gene Expression Profile Inflammatory Index; and using the Gene Expression Profile Inflammatory Index in determining the property.

In accordance with another embodiment there is provided a method of providing an index that is indicative of the biological state of a subject based on a sample from the subject.

The method of this embodiment includes:

-   -   deriving from the sample a first profile data set, the first         profile data set including a plurality of members, each member         being a quantitative measure of the amount of a distinct RNA or         protein constituent in a panel of constituents, the panel         including at least two of the constituents of the Inflammation         Gene Expression Panel of Table 1; and     -   applying values from the first profile data set to an index         function that provides a mapping from an instance of a profile         data set into a single-valued measure of biological condition,         so as to produce an index pertinent to the biological condition         of the sample or the subject.

In carrying out this method the index function also uses data from a baseline profile data set for the panel. Each member of the baseline data set is a normative measure, determined with respect to a relevant population of subjects, of the amount of one of the constituents in the panel. In addition, in deriving the first profile data set and the baseline data set, such measure is performed for each constituent both under conditions wherein specificity and efficiencies of amplification for all constituents are substantially similar and under substantially repeatable conditions.

In another type of embodiment, there is provided a method, for evaluating a biological condition of a subject, based on a sample from the subject. In this embodiment, the method includes:

-   -   deriving from the sample a first profile data set, the first         profile data set including a plurality of members, each member         being a quantitative measure of the amount of a distinct RNA or         protein constituent in a panel of constituents selected so that         measurement of the constituents enables measurement of the         biological condition; and     -   producing a calibrated profile data set for the panel, wherein         each member of the calibrated profile data set is a function of         a corresponding member of the first profile data set and a         corresponding member of a baseline profile data set for the         panel.

In this embodiment, each member of the baseline data set is a normative measure, determined with respect to a relevant population of subjects, of the amount of one of the constituents in the panel, and the calibrated profile data set provides a measure of the biological condition of the subject.

In a similar type of embodiment, there is provided a method, for evaluating a biological condition of a subject, based on a sample from the subject, and the method of this embodiment includes:

-   -   applying the first sample or a portion thereof to a defined         population of indicator cells;     -   obtaining from the indicator cells a second sample containing at         least one of RNAs or proteins;     -   deriving from the second sample a first profile data set, the         first profile data set including a plurality of members, each         member being a quantitative measure of the amount of a distinct         RNA or protein constituent in a panel of constituents selected         so that measurement of the constituents enables measurement of         the biological condition; and     -   producing a calibrated profile data set for the panel, wherein         each member of the calibrated profile data set is a function of         a corresponding member of the first profile data set and a         corresponding member of a baseline profile data set for the         panel, wherein each member of the baseline data set is a         normative measure, determined with respect to a relevant         population of subjects, of the amount of one of the constituents         in the panel, the calibrated profile data set providing a         measure of the biological condition of the subject.

Furthermore, another and similar, type of embodiment provides a method, for evaluating a biological condition affected by an agent. The method of this embodiment includes:

-   -   obtaining, from a target population of cells to which the agent         has been administered, a sample having at least one of RNAs and         proteins;     -   deriving from the sample a first profile data set, the first         profile data set including a plurality of members, each member         being a quantitative measure of the amount of a distinct RNA or         protein constituent in a panel of constituents selected so that         measurement of the constituents enables measurement of the         biological condition; and     -   producing a calibrated profile data set for the panel, wherein         each member of the calibrated profile data set is a function of         a corresponding member of the first profile data set and a         corresponding member of a baseline profile data set for the         panel, wherein each member of the baseline data set is a         normative measure, determined with respect to a relevant         population of subjects, of the amount of one of the constituents         in the panel, the calibrated profile data set providing a         measure of the biological condition as affected by the agent.

In further embodiments based on these last three embodiments, the relevant population may be a population of healthy subjects. Alternatively, or in addition, the relevant population has in common a property that is at least one of age group, gender, ethnicity, geographic location, diet, medical disorder, clinical indicator, medication, physical activity, body mass, and environmental exposure.

Alternatively or in addition, the panel includes at least two of the constituents of the Inflammation Gene Expression Panel of Table 1. (Other embodiments employ at least three, four, five, six, or ten of such constituents.) Also alternatively or in addition, in deriving the first profile data set, such measure is performed for each constituent both under conditions wherein specificity and efficiencies of amplification for all constituents are substantially similar and under substantially repeatable conditions. Also alternatively, when such measure is performed for each constituent both under conditions wherein specificity and efficiencies of amplification for all constituents are substantially similar and under substantially repeatable conditions, optionally one need not produce a calibrated profile data set, but may instead work directly with the first data set.

In another embodiment, there is provided a method, for evaluating the effect on a biological condition by a first agent in relation to the effect by a second agent. The method of this embodiment includes:

-   -   obtaining, from first and second target populations of cells to         which the first and second agents have been respectively         administered, first and second samples respectively, each sample         having at least one of RNAs and proteins;     -   deriving from the first sample a first profile data set and from         the second sample a second profile data set, the profile data         sets each including a plurality of members, each member being a         quantitative measure of the amount of a distinct RNA or protein         constituent in a panel of constituents selected so that         measurement of the constituents enables measurement of the         biological condition; and     -   producing for the panel a first calibrated profile data set and         a second profile data set, wherein (i) each member of the first         calibrated profile data set is a function of a corresponding         member of the first profile data set and a corresponding member         of a baseline profile data set for the panel, wherein each         member of the baseline data set is a normative measure,         determined with respect to a relevant population of subjects, of         the amount of one of the constituents in the panel, and (ii)         each member of the second calibrated profile data set is a         function of a corresponding member of the second profile data         set and a corresponding member of the baseline profile data set,         the calibrated profile data sets providing a measure of the         effect by the first agent on the biological condition in         relation to the effect by the second agent.

In this embodiment, in deriving the first and second profile data sets, such measure is performed for each constituent both under conditions wherein specificity and efficiencies of amplification for all constituents are substantially similar and under substantially repeatable conditions. In a further related embodiment, the first agent is a first drug and the second agent is a second drug. In another related embodiment, the first agent is a drug and the second agent is a complex mixture. In yet another related embodiment, the first agent is a drug and the second agent is a nutriceutical.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing features of the invention will be more readily understood by reference to the following detailed description, taken with reference to the accompanying drawings, in which:

FIG. 1A shows the results of assaying 24 genes from the Source Inflammation Gene Panel (shown in Table 1) on eight separate days during the course of optic neuritis in a single male subject.

FIG. 1B illustrates use of an inflammation index in relation to the data of FIG. 1A, in accordance with an embodiment of the present invention.

FIG. 2 is a graphical illustration of the same inflammation index calculated at 9 different, significant clinical milestones.

FIG. 3 shows the effects of single dose treatment with 800 mg of ibuprofen in a single donor as characterized by the index.

FIG. 4 shows the calculated acute inflammation index displayed graphically for five different conditions.

FIG. 5 shows a Viral Response Index for monitoring the progress of an upper respiratory infection (URI).

FIGS. 6 and 7 compare two different populations using Gene Expression Profiles (with respect to the 48 loci of the Inflammation Gene Expression Panel of Table 1).

FIG. 8 compares a normal population with a rheumatoid arthritis population derived from a longitudinal study.

FIG. 9 compares two normal populations, one longitudinal and the other cross sectional.

FIG. 10 shows the shows gene expression values for various individuals of a normal population.

FIG. 11 shows the expression levels for each of four genes (of the Inflammation Gene Expression Panel of Table 1), of a single subject, assayed monthly over a period of eight months.

FIGS. 12 and 13 similarly show in each case the expression levels for each of 48 genes (of the Inflammation Gene Expression Panel of Table 1), of distinct single subjects (selected in each case on the basis of feeling well and not taking drugs), assayed, in the case of FIG. 12 weekly over a period of four weeks, and in the case of FIG. 13 monthly over a period of six months.

FIG. 14 shows the effect over time, on inflammatory gene expression in a single human subject, of the administration of an anti-inflammatory steroid, as assayed using the Inflammation Gene Expression Panel of Table 1.

FIG. 15, in a manner analogous to FIG. 14, shows the effect over time, via whole blood samples obtained from a human subject, administered a single dose of prednisone, on expression of 5 genes (of the Inflammation Gene Expression Panel of Table 1).

FIG. 16 also shows the effect over time, on inflammatory gene expression in a single human subject suffering from rheumatoid arthritis, of the administration of a TNF-inhibiting compound, but here the expression is shown in comparison to the cognate locus average previously determined (in connection with FIGS. 6 and 7) for the normal (i.e., undiagnosed, healthy) population.

FIG. 17A further illustrates the consistency of inflammatory gene expression in a population.

FIG. 17B shows the normal distribution of index values obtained from an undiagnosed population.

FIG. 17C illustrates the use of the same index as FIG. 17B, where the inflammation median for a normal population has been set to zero and both normal and diseased subjects are plotted in standard deviation units relative to that median.

FIG. 18 plots, in a fashion similar to that of FIG. 17A, Gene Expression Profiles, for the same 7 loci as in FIG. 17A, two different (responder v. non-responder) 6-subject populations of rheumatoid arthritis patients.

FIG. 19 thus illustrates use of the inflammation index for assessment of a single subject suffering from rheumatoid arthritis, who has not responded well to traditional therapy with methotrexate.

FIG. 20 similarly illustrates use of the inflammation index for assessment of three subjects suffering from rheumatoid arthritis, who have not responded well to traditional therapy with methotrexate.

Each of FIGS. 21-23 shows the inflammation index for an international group of subjects, suffering from rheumatoid arthritis, undergoing three separate treatment regimens.

FIG. 24 illustrates use of the inflammation index for assessment of a single subject suffering from inflammatory bowel disease.

FIG. 25 shows Gene Expression Profiles with respect to 24 loci (of the Inflammation Gene Expression Panel of Table 1) for whole blood treated with Ibuprofen in vitro in relation to other non-steroidal anti-inflammatory drugs (NSAIDs).

FIG. 26 illustrates how the effects of two competing anti-inflammatory compounds can be compared objectively, quantitatively, precisely, and reproducibly.

FIGS. 27 through 41 illustrate the use of gene expression panels in early identification and monitoring of infectious disease.

FIG. 27 uses a novel bacterial Gene Expression Panel of 24 genes, developed to discriminate various bacterial conditions in a host biological system.

FIG. 28 shows differential expression for a single locus, IFNG, to LTA derived from three distinct sources: S. pyogenes, B. subtilis, and S. aureus.

FIGS. 29 and 30 show the response after two hours of the Inflammation 48A and 48B loci respectively (discussed above in connection with FIGS. 6 and 7 respectively) in whole blood to administration of a Gram-positive and a Gram-negative organism.

FIGS. 31 and 32 correspond to FIGS. 29 and 30 respectively and are similar to them, with the exception that the monitoring here occurs 6 hours after administration.

FIG. 33 compares the gene expression response induced by E. coli and by an organism-free E. coli filtrate.

FIG. 34 is similar to FIG. 33, but here the compared responses are to stimuli from E. coli filtrate alone and from E. coli filtrate to which has been added polymyxin B.

FIG. 35 illustrates the gene expression responses induced by S. aureus at 2, 6, and 24 hours after administration.

FIGS. 36 through 41 compare the gene expression induced by E. coli and S. aureus under various concentrations and times.

DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS Definitions

The following terms shall have the meanings indicated unless the context otherwise requires:

“Algorithm” is a set of rules for describing a biological condition. The rule set may be defined exclusively algebraically but may also include alternative or multiple decision points requiring domain-specific knowledge, expert interpretation or other clinical indicators.

An “agent” is a “composition” or a “stimulus”, as those terms are defined herein, or a combination of a composition and a stimulus.

“Amplification” in the context of a quantitative RT-PCR assay is a function of the number of DNA replications that are tracked to provide a quantitative determination of its concentration. “Amplification” here refers to a degree of sensitivity and specificity of a quantitative assay technique. Accordingly, amplification provides a measurement of concentrations of constituents that is evaluated under conditions wherein the efficiency of amplification and therefore the degree of sensitivity and reproducibility for measuring all constituents is substantially similar.

A “baseline profile data set” is a set of values associated with constituents of a Gene Expression Panel resulting from evaluation of a biological sample (or population of samples) under a desired biological condition that is used for mathematically normative purposes. The desired biological condition may be, for example, the condition of a subject (or population of subjects) before exposure to an agent or in the presence of an untreated disease or in the absence of a disease. Alternatively, or in addition, the desired biological condition may be health of a subject or a population of subjects. Alternatively, or in addition, the desired biological condition may be that associated with a population of subjects selected on the basis of at least one of age group, gender, ethnicity, geographic location, diet, medical disorder, clinical indicator, medication, physical activity, body mass, and environmental exposure.

A “biological condition” of a subject is the condition of the subject in a pertinent realm that is under observation, and such realm may include any aspect of the subject capable of being monitored for change in condition, such as health, disease including cancer; trauma; aging; infection; tissue degeneration; developmental steps; physical fitness; obesity, and mood. As can be seen, a condition in this context may be chronic or acute or simply transient. Moreover, a targeted biological condition may be manifest throughout the organism or population of cells or may be restricted to a specific organ (such as skin, heart, eye or blood), but in either case, the condition may be monitored directly by a sample of the affected population of cells or indirectly by a sample derived elsewhere from the subject. The term “biological condition” includes a “physiological condition”.

“Body fluid” of a subject includes blood, urine, spinal fluid, lymph, mucosal secretions, prostatic fluid, semen, haemolymph or any other body fluid known in the art for a subject.

“Calibrated profile data set” is a function of a member of a first profile data set and a corresponding member of a baseline profile data set for a given constituent in a panel.

A “clinical indicator” is any physiological datum used alone or in conjunction with other data in evaluating the physiological condition of a collection of cells or of an organism. This term includes pre-clinical indicators.

A “composition” includes a chemical compound, a nutriceutical, a pharmaceutical, a homeopathic formulation, an allopathic formulation, a naturopathic formulation, a combination of compounds, a toxin, a food, a food supplement, a mineral, and a complex mixture of substances, in any physical state or in a combination of physical states.

To “derive” a profile data set from a sample includes determining a set of values associated with constituents of a Gene Expression Panel either (i) by direct measurement of such constituents in a biological sample or (ii) by measurement of such constituents in a second biological sample that has been exposed to the original sample or to matter derived from the original sample.

“Distinct RNA or protein constituent” in a panel of constituents is a distinct expressed product of a gene, whether RNA or protein. An “expression” product of a gene includes the gene product whether RNA or protein resulting from translation of the messenger RNA.

A “Gene Expression Panel” is an experimentally verified set of constituents, each constituent being a distinct expressed product of a gene, whether RNA or protein, wherein constituents of the set are selected so that their measurement provides a measurement of a targeted biological condition.

A “Gene Expression Profile” is a set of values associated with constituents of a Gene Expression Panel resulting from evaluation of a biological sample (or population of samples).

A “Gene Expression Profile Inflammatory Index” is the value of an index function that provides a mapping from an instance of a Gene Expression Profile into a single-valued measure of inflammatory condition.

The “health” of a subject includes mental, emotional, physical, spiritual, allopathic, naturopathic and homeopathic condition of the subject.

“Index” is an arithmetically or mathematically derived numerical characteristic developed for aid in simplifying or disclosing or informing the analysis of more complex quantitative information. A disease or population index may be determined by the application of a specific algorithm to a plurality of subjects or samples with a common biological condition.

“Inflammation” is used herein in the general medical sense of the word and may be an acute or chronic; simple or supporative; localized or disseminated; cellular and tissue response, initiated or sustained by any number of chemical, physical or biological agents or combination of agents.

“Inflammatory state” is used to indicate the relative biological condition of a subject resulting from inflammation, or characterizing the degree of inflammation.

A “large number” of data sets based on a common panel of genes is a number of data sets sufficiently large to permit a statistically significant conclusion to be drawn with respect to an instance of a data set based on the same panel.

A “normative” condition of a subject to whom a composition is to be administered means the condition of a subject before administration, even if the subject happens to be suffering from a disease.

A “panel” of genes is a set of genes including at least two constituents.

A “sample” from a subject may include a single cell or multiple cells or fragments of cells or an aliquot of body fluid, taken from the subject, by means including venipuncture, excretion, ejaculation, massage, biopsy, needle aspirate, lavage sample, scraping, surgical incision or intervention or other means known in the art.

A “Signature Profile” is an experimentally verified subset of a Gene Expression Profile selected to discriminate a biological condition, agent or physiological mechanism of action.

A “Signature Panel” is a subset of a Gene Expression Panel, the constituents of which are selected to permit discrimination of a biological condition, agent or physiological mechanism of action.

A “subject” is a cell, tissue, or organism, human or non-human, whether in vivo, ex vivo or in vitro, under observation. When we refer to evaluating the biological condition of a subject based on a sample from the subject, we include using blood or other tissue sample from a human subject to evaluate the human subject's condition; but we also include, for example, using a blood sample itself as the subject to evaluate, for example, the effect of therapy or an agent upon the sample.

A “stimulus” includes (i) a monitored physical interaction with a subject, for example ultraviolet A or B, or light therapy for seasonal affective disorder, or treatment of psoriasis with psoralen or treatment of melanoma with embedded radioactive seeds, other radiation exposure, and (ii) any monitored physical, mental, emotional, or spiritual activity or inactivity of a subject.

“Therapy” includes all interventions whether biological, chemical, physical, metaphysical, or combination of the foregoing, intended to sustain or alter the monitored biological condition of a subject.

The PCT patent application publication number WO 01/25473, published Apr. 12, 2001, entitled “Systems and Methods for Characterizing a Biological Condition or Agent Using Calibrated Gene Expression Profiles,” filed for an invention by inventors herein, and which is herein incorporated by reference, discloses the use of Gene Expression Panels for the evaluation of (i) biological condition (including with respect to health and disease) and (ii) the effect of one or more agents on biological condition (including with respect to health, toxicity, therapeutic treatment and drug interaction).

In particular, Gene Expression Panels may be used for measurement of therapeutic efficacy of natural or synthetic compositions or stimuli that may be formulated individually or in combinations or mixtures for a range of targeted physiological conditions; prediction of toxicological effects and dose effectiveness of a composition or mixture of compositions for an individual or in a population; determination of how two or more different agents administered in a single treatment might interact so as to detect any of synergistic, additive, negative, neutral or toxic activity; performing pre-clinical and clinical trials by providing new criteria for pre-selecting subjects according to informative profile data sets for revealing disease status; and conducting preliminary dosage studies for these patients prior to conducting phase 1 or 2 trials. These Gene Expression Panels may be employed with respect to samples derived from subjects in order to evaluate their biological condition.

A Gene Expression Panel is selected in a manner so that quantitative measurement of RNA or protein constituents in the Panel constitutes a measurement of a biological condition of a subject. In one kind of arrangement, a calibrated profile data set is employed. Each member of the calibrated profile data set is a function of (i) a measure of a distinct constituent of a Gene Expression Panel and (ii) a baseline quantity.

We have found that valuable and unexpected results may be achieved when the quantitative measurement of constituents is performed under repeatable conditions (within a degree of repeatability of measurement of better than twenty percent, and preferably five percent or better, and more preferably three percent or better). For the purposes of this description and the following claims, we regard a degree of repeatability of measurement of better than twenty percent as providing measurement conditions that are “substantially repeatable”. In particular, it is desirable that, each time a measurement is obtained corresponding to the level of expression of a constituent in a particular sample, substantially the same measurement should result for the substantially the same level of expression. In this manner, expression levels for a constituent in a Gene Expression Panel may be meaningfully compared from sample to sample. Even if the expression level measurements for a particular constituent are inaccurate (for example, say, 30% too low), the criterion of repeatability means that all measurements for this constituent, if skewed, will nevertheless be skewed systematically, and therefore measurements of expression level of the constituent may be compared meaningfully. In this fashion valuable information may be obtained and compared concerning expression of the constituent under varied circumstances.

In addition to the criterion of repeatability, it is desirable that a second criterion also be satisfied, namely that quantitative measurement of constituents is performed under conditions wherein efficiencies of amplification for all constituents are substantially similar (within one to two percent and typically one percent or less). When both of these criteria are satisfied, then measurement of the expression level of one constituent may be meaningfully compared with measurement of the expression level of another constituent in a given sample and from sample to sample.

Present embodiments relate to the use of an index or algorithm resulting from quantitative measurement of constituents, and optionally in addition, derived from either expert analysis or computational biology (a) in the analysis of complex data sets; (b) to control or normalize the influence of uninformative or otherwise minor variances in gene expression values between samples or subjects; (c) to simplify the characterization of a complex data set for comparison to other complex data sets, databases or indices or algorithms derived from complex data sets; (d) to monitor a biological condition of a subject; (e) for measurement of therapeutic efficacy of natural or synthetic compositions or stimuli that may be formulated individually or in combinations or mixtures for a range of targeted physiological conditions; (f) for predictions of toxicological effects and dose effectiveness of a composition or mixture of compositions for an individual or in a population; (g) for determination of how two or more different agents administered in a single treatment might interact so as to detect any of synergistic, additive, negative, neutral of toxic activity (h) for performing pre-clinical and clinical trials by providing new criteria for pre-selecting subjects according to informative profile data sets for revealing disease status and conducting preliminary dosage studies for these patients prior to conducting phase 1 or 2 trials.

Gene expression profiling and the use of index characterization for a particular condition or agent or both may be used to reduce the cost of phase 3 clinical trials and may be used beyond phase 3 trials; labeling for approved drugs; selection of suitable medication in a class of medications for a particular patient that is directed to their unique physiology; diagnosing or determining a prognosis of a medical condition or an infection which may precede onset of symptoms or alternatively diagnosing adverse side effects associated with administration of a therapeutic agent; managing the health care of a patient; and quality control for different batches of an agent or a mixture of agents.

The Subject

The methods disclosed here may be applied to cells of humans, mammals or other organisms without the need for undue experimentation by one of ordinary skill in the art because all cells transcribe RNA and it is known in the art how to extract RNA from all types of cells.

Selecting Constituents of a Gene Expression Panel

The general approach to selecting constituents of a Gene Expression Panel has been described in PCT application publication number WO 01/25473. We have designed and experimentally verified a wide range of Gene Expression Panels, each panel providing a quantitative measure, of biological condition, that is derived from a sample of blood or other tissue. For each panel, experiments have verified that a Gene Expression Profile using the panel's constituents is informative of a biological condition. (We show elsewhere that in being informative of biological condition, the Gene Expression Profile can be used, among other things, to measure the effectiveness of therapy, as well as to provide a target for therapeutic intervention.) Examples of Gene Expression Panels, along with a brief description of each panel constituent, are provided in tables attached hereto as follows:

-   -   Table 1. Inflammation Gene Expression Panel     -   Table 2. Diabetes Gene Expression Panel     -   Table 3. Prostate Gene Expression Panel     -   Table 4. Skin Response Gene Expression Panel     -   Table 5. Liver Metabolism and Disease Gene Expression Panel     -   Table 6. Endothelial Gene Expression Panel     -   Table 7. Cell Health and Apoptosis Gene Expression Panel     -   Table 8. Cytokine Gene Expression Panel     -   Table 9. TNF/IL1 Inhibition Gene Expression Panel     -   Table 10. Chemokine Gene Expression Panel     -   Table 11. Breast Cancer Gene Expression Panel     -   Table 12. Infectious Disease Gene Expression Panel

Other panels may be constructed and experimentally verified by one of ordinary skill in the art in accordance with the principles articulated in the present application.

Design of Assays

We commonly run a sample through a panel in quadruplicate; that is, a sample is divided into aliquots and for each aliquot we measure concentrations of each constituent in a Gene Expression Panel. Over a total of 900 constituent assays, with each assay conducted in quadruplicate, we found an average coefficient of variation, (standard deviation/average)*100, of less than 2 percent, typically less than 1 percent, among results for each assay. This figure is a measure of what we call “intra-assay variability”. We have also conducted assays on different occasions using the same sample material. With 72 assays, resulting from concentration measurements of constituents in a panel of 24 members, and such concentration measurements determined on three different occasions over time, we found an average coefficient of variation of less than 5 percent, typically less than 2 percent. We regard this as a measure of what we call “inter-assay variability”.

We have found it valuable in using the quadruplicate test results to identify and eliminate data points that are statistical “outliers”; such data points are those that differ by a percentage greater, for example, than 3% of the average of all four values and that do not result from any systematic skew that is greater, for example, than 1%. Moreover, if more than one data point in a set of four is excluded by this procedure, then all data for the relevant constituent is discarded.

Measurement of Gene Expression for a Constituent in the Panel

For measuring the amount of a particular RNA in a sample, we have used methods known to one of ordinary skill in the art to extract and quantify transcribed RNA from a sample with respect to a constituent of a Gene Expression Panel. (See detailed protocols below. Also see PCT application publication number WO 98/24935 herein incorporated by reference for RNA analysis protocols). Briefly, RNA is extracted from a sample such as a tissue, body fluid, or culture medium in which a population of a subject might be growing. For example, cells may be lysed and RNA eluted in a suitable solution in which to conduct a DNAse reaction. First strand synthesis may be performed using a reverse transcriptase. Gene amplification, more specifically quantitative PCR assays, can then conducted and the gene of interest size calibrated against a marker such as 18S rRNA (Hirayama et al., Blood 92, 1998: 46-52). Samples are measured in multiple duplicates, for example, 4 replicates. Relative quantitation of the mRNA is determined by the difference in threshhold cycles between the internal control and the gene of interest. In an embodiment of the invention, quantitative PCR is performed using amplification, reporting agents and instruments such as those supplied commercially by Applied Biosystems (Foster City, Calif.). Given a defined efficiency of amplification of target transcripts, the point (e.g., cycle number) that signal from amplified target template is detectable may be directly related to the amount of specific message transcript in the measured sample. Similarly, other quantifiable signals such as fluorescence, enzyme activity, disintegrations per minute, absorbance, etc., when correlated to a known concentration of target templates (e.g., a reference standard curve) or normalized to a standard with limited variability can be used to quantify the number of target templates in an unknown sample.

Although not limited to amplification methods, quantitative gene expression techniques may utilize amplification of the target transcript. Alternatively or in combination with amplification of the target transcript, amplification of the reporter signal may also be used. Amplification of the target template may be accomplished by isothermic gene amplification strategies, or by gene amplification by thermal cycling such as PCR.

It is desirable to obtain a definable and reproducible correlation between the amplified target or reporter and the concentration of starting templates. We have discovered that this objective can be achieved by careful attention to, for example, consistent primer-template ratios and a strict adherence to a narrow permissible level of experimental amplification efficiencies (for example 99.0 to 100% relative efficiency, typically 99.8 to 100% relative efficiency). For example, in determining gene expression levels with regard to a single Gene Expression Profile, it is necessary that all constituents of the panels maintain a similar and limited range of primer template ratios (for example, within a 10-fold range) and amplification efficiencies (within, for example, less than 1%) to permit accurate and precise relative measurements for each constituent. We regard amplification efficiencies as being “substantially similar”, for the purposes of this description and the following claims, if they differ by no more than approximately 10%. Preferably they should differ by less than approximately 2% and more preferably by less than approximately 1%. These constraints should be observed over the entire range of concentration levels to be measured associated with the relevant biological condition. While it is thus necessary for various embodiments herein to satisfy criteria that measurements are achieved under measurement conditions that are substantially repeatable and wherein specificity and efficiencies of amplification for all constituents are substantially similar, nevertheless, it is within the scope of the present invention as claimed herein to achieve such measurement conditions by adjusting assay results that do not satisfy these criteria directly, in such a manner as to compensate for errors, so that the criteria are satisfied after suitable adjustment of assay results.

In practice, we run tests to assure that these conditions are satisfied. For example, we typically design and manufacture a number of primer-probe sets, and determine experimentally which set gives the best performance. Even though primer-probe design and manufacture can be enhanced using computer techniques known in the art, and notwithstanding common practice, we still find that experimental validation is useful. Moreover, in the course of experimental validation, we associate with the selected primer-probe combination a set of features:

The reverse primer should be complementary to the coding DNA strand. In one embodiment, the primer should be located across an intron-exon junction, with not more than three bases of the three-prime end of the reverse primer complementary to the proximal exon. (If more than three bases are complementary, then it would tend to competitively amplify genomic DNA.)

In an embodiment of the invention, the primer probe should amplify cDNA of less than 110 bases in length and should not amplify genomic DNA or transcripts or cDNA from related but biologically irrelevant loci.

A suitable target of the selected primer probe is first strand cDNA, which may be prepared, in one embodiment, is described as follows:

(a) Use of whole blood for ex vivo assessment of a biological condition affected by an agent.

Human blood is obtained by venipuncture and prepared for assay by separating samples for baseline, no stimulus, and stimulus with sufficient volume for at least three time points. Typical stimuli include lipopolysaccharide (LPS), phytohemagglutinin (PHA) and heat-killed staphylococci (HKS) or carrageean and may be used individually (typically) or in combination. The aliquots of heparinized, whole blood are mixed without stimulus and held at 37° C. in an atmosphere of 5% CO₂ for 30 minutes. Stimulus is added at varying concentrations, mixed and held loosely capped at 37° C. for 30 min. Additional test compounds may be added at this point and held for varying times depending on the expected pharmacokinetics of the test compound. At defined times, cells are collected by centrifugation, the plasma removed and RNA extracted by various standard means.

Nucleic acids, RNA and or DNA are purified from cells, tissues or fluids of the test population or indicator cell lines. RNA is preferentially obtained from the nucleic acid mix using a variety of standard procedures (or RNA Isolation Strategies, pp. 55-104, in RNA Methodologies, A laboratory guide for isolation and characterization, 2nd edition, 1998, Robert E. Farrell, Jr., Ed., Academic Press), in the present using a filter-based RNA isolation system from Ambion (RNAqueous™, Phenol-free Total RNA Isolation Kit, Catalog #1912, version 9908; Austin, Tex.).

In accordance with one procedure, the whole blood assay for Gene Expression Profiles determination was carried out as follows: Human whole blood was drawn into 10 mL Vacutainer tubes with Sodium Heparin. Blood samples were mixed by gently inverting tubes 4-5 times. The blood was used within 10-15 minutes of draw. In the experiments, blood was diluted 2-fold, i.e. per sample per time point, 0.6 mL whole blood+0.6 mL stimulus. The assay medium was prepared and the stimulus added as appropriate.

A quantity (0.6 mL) of whole blood was then added into each 12×75 mm polypropylene tube. 0.6 mL of 2×LPS (from E. coli serotype 0127:B8, Sigma#L3880 or serotype 055, Sigma #L4005, 10 ng/ml, subject to change in different lots) into LPS tubes was added. Next, 0.6 mL assay medium was added to the “control” tubes with duplicate tubes for each condition. The caps were closed tightly. The tubes were inverted 2-3 times to mix samples. Caps were loosened to first stop and the tubes incubated@37° C., 5% CO₂ for 6 hours. At 6 hours, samples were gently mixed to resuspend blood cells, and 1 mL was removed from each tube (using a micropipettor with barrier tip), and transfered to a 2 mL “dolphin” microfuge tube (Costar #3213).

The samples were then centrifuged for 5 min at 500×g, ambient temperature (IEC centrifuge or equivalent, in microfuge tube adapters in swinging bucket), and as much serum from each tube was removed as possible and discarded. Cell pellets were placed on ice; and RNA extracted as soon as possible using an Ambion RNAqueous kit.

-   -   a) Amplification Strategies.

Specific RNAs are amplified using message specific primers or random primers. The specific primers are synthesized from data obtained from public databases (e.g., Unigene, National Center for Biotechnology Information, National Library of Medicine, Bethesda, Md.), including information from genomic and cDNA libraries obtained from humans and other animals. Primers are chosen to preferentially amplify from specific RNAs obtained from the test or indicator samples, see, for example, RT PCR, Chapter 15 in RNA Methodologies, A laboratory guide for isolation and characterization, 2nd edition, 1998, Robert E. Farrell, Jr., Ed., Academic Press; or Chapter 22 pp. 143-151, RNA isolation and characterization protocols, Methods in molecular biology, Volume 86, 1998, R. Rapley and D. L. Manning Eds., Human Press, or 14 in Statistical refinement of primer design parameters, Chapter 5, pp. 55-72, PCR applications: protocols for functional genomics, M. A. Innis, D. H. Gelfand and J. J. Sninsky, Eds., 1999, Academic Press). Amplifications are carried out in either isothermic conditions or using a thermal cycler (for example, ABI 9600 or 9700 or 7700 obtained from Applied Biosystems, Foster City, Calif.; see Nucleic acid detection methods, pp. 1-24, in Molecular methods for virus detection, D. L. Wiedbrauk and D. H., Farkas, Eds., 1995, Academic Press). Amplified nucleic acids are detected using fluorescent-tagged detection primers (see, for example, Taqman™ PCR Reagent Kit, Protocol, part number 402823 revision A, 1996, Applied Biosystems, Foster City Calif.) that are identified and synthesized from publicly known databases as described for the amplification primers. In the present case, amplified DNA is detected and quantified using the ABI Prism 7700 Sequence Detection System obtained from Applied Biosystems (Foster City, Calif.). Amounts of specific RNAs contained in the test sample or obtained from the indicator cell lines can be related to the relative quantity of fluorescence observed (see for example, Advances in quantitative PCR technology: 5′ nuclease assays, Y. S. Lie and C. J. Petropolus, Current Opinion in Biotechnology, 1998, 9:43-48, or Rapid thermal cycling and PCR kinetics, pp. 211-229, chapter 14 in PCR applications: protocols for functional genomics, M. A. Innis, D. H. Gelfand and J. J. Sninsky, Eds., 1999, Academic Press).

As a particular implementation of the approach described here, we describe in detail a procedure for synthesis of first strand cDNA for use in PCR. This procedure can be used for both whole blood RNA and RNA extracted from cultured cells (i.e. THP-1 cells).

Materials

1. Applied Biosystems TAQMAN Reverse Transcription Reagents Kit (P/N 808-0234). Kit Components: 10× TaqMan RT Buffer, 25 mM Magnesium chloride, deoxyNTPs mixture, Random Hexamers, RNase Inhibitor, MultiScribe Reverse Transcriptase (50 U/mL) (2) RNase/DNase free water (DEPC Treated Water from Ambion (P/N 9915G), or equivalent)

Methods

1. Place RNase Inhibitor and MultiScribe Reverse Transcriptase on ice immediately. All other reagents can be thawed at room temperature and then placed on ice.

2. Remove RNA samples from −80° C. freezer and thaw at room temperature and then place immediately on ice.

3. Prepare the following cocktail of Reverse Transcriptase Reagents for each 100 mL RT reaction (for multiple samples, prepare extra cocktail to allow for pipetting error):

1 reaction (mL) 11X, e.g. 10 samples (mL) 10× RT Buffer 10.0 110.0 25 mM MgCl2 22.0 242.0 dNTPs 20.0 220.0 Random Hexamers 5.0 55.0 RNAse Inhibitor 2.0 22.0 Reverse Transcriptase 2.5 27.5 Water 18.5 203.5 Total: 80.0 880.0 (80 mL per sample)

4. Bring each RNA sample to a total volume of 20 mL in a 1.5 mL microcentrifuge tube (for example, for THP-1 RNA, remove 10 mL RNA and dilute to 20 mL with RNase/DNase free water, for whole blood RNA use 20 mL total RNA) and add 80 mL RT reaction mix from step 5, 2, 3. Mix by pipetting up and down.

5. Incubate sample at room temperature for 10 minutes.

6. Incubate sample at 37° C. for 1 hour.

7. Incubate sample at 90° C. for 10 minutes.

8. Quick spin samples in microcentrifuge.

9. Place sample on ice if doing PCR immediately, otherwise store sample at −20° C. for future use.

10. PCR QC should be run on all RT samples using 18 S and b-actin (see SOP 200-020).

The use of the primer probe with the first strand cDNA as described above to permit measurement of constituents of a Gene Expression Panel is as follows:

Set up of a 24-gene Human Gene Expression Panel for Inflammation.

Materials

1. 20× Primer/Probe Mix for each gene of interest.

2. 20× Primer/Probe Mix for 18S endogenous control.

3. 2× Taqman Universal PCR Master Mix.

4. cDNA transcribed from RNA extracted from cells.

5. Applied Biosystems 96-Well Optical Reaction Plates.

6. Applied Biosystems Optical Caps, or optical-clear film.

7. Applied Biosystem Prism 7700 Sequence Detector.

Methods

1. Make stocks of each Primer/Probe mix containing the Primer/Probe for the gene of interest, Primer/Probe for 18S endogenous control, and 2.times.PCR Master Mix as follows. Make sufficient excess to allow for pipetting error e.g. approximately 10% excess. The following example illustrates a typical set up for one gene with quadruplicate samples testing two conditions (2 plates).

9X 1X (1 well) (2 plates worth)  2X Master Mix 12.50 112.50 20X 18S Primer/Probe Mix 1.25 11.25 20X Gene of interest Primer/Probe Mix 1.25 11.25 Total 15.00 135.00

2. Make stocks of cDNA targets by diluting 95 μl of cDNA into 2000 μl of water. The amount of cDNA is adjusted to give Ct values between 10 and 18, typically between 12 and 13.

3. Pipette 15 μl of Primer/Probe mix into the appropriate wells of an Applied Biosystems 96-Well Optical Reaction Plate.

4. Pipette 10 μl of cDNA stock solution into each well of the Applied Biosystems 96-Well Optical Reaction Plate.

5. Seal the plate with Applied Biosystems Optical Caps, or optical-clear film.

6. Analyze the plate on the AB Prism 7700 Sequence Detector.

Methods herein may also be applied using proteins where sensitive quantitative techniques, such as an Enzyme Linked ImmunoSorbent Assay (ELISA) or mass spectroscopy, are available and well-known in the art for measuring the amount of a protein constituent. (see WO 98/24935 herein incorporated by reference).

Baseline Profile Data Sets

The analyses of samples from single individuals and from large groups of individuals provide a library of profile data sets relating to a particular panel or series of panels. These profile data sets may be stored as records in a library for use as baseline profile data sets. As the term “baseline” suggests, the stored baseline profile data sets serve as comparators for providing a calibrated profile data set that is informative about a biological condition or agent. Baseline profile data sets may be stored in libraries and classified in a number of cross-referential ways. One form of classification may rely on the characteristics of the panels from which the data sets are derived. Another form of classification may be by particular biological condition. The concept of biological condition encompasses any state in which a cell or population of cells may be found at any one time. This state may reflect geography of samples, sex of subjects or any other discriminator. Some of the discriminators may overlap. The libraries may also be accessed for records associated with a single subject or particular clinical trial. The classification of baseline profile data sets may further be annotated with medical information about a particular subject, a medical condition, a particular agent etc.

The choice of a baseline profile data set for creating a calibrated profile data set is related to the biological condition to be evaluated, monitored, or predicted, as well as, the intended use of the calibrated panel, e.g., as to monitor drug development, quality control or other uses. It may be desirable to access baseline profile data sets from the same subject for whom a first profile data set is obtained or from different subject at varying times, exposures to stimuli, drugs or complex compounds; or may be derived from like or dissimilar populations.

The profile data set may arise from the same subject for which the first data set is obtained, where the sample is taken at a separate or similar time, a different or similar site or in a different or similar physiological condition. For example, FIG. 5 provides a protocol in which the sample is taken before stimulation or after stimulation. The profile data set obtained from the unstimulated sample may serve as a baseline profile data set for the sample taken after stimulation. The baseline data set may also be derived from a library containing profile data sets of a population of subjects having some defining characteristic or biological condition. The baseline profile data set may also correspond to some ex vivo or in vitro properties associated with an in vitro cell culture. The resultant calibrated profile data sets may then be stored as a record in a database or library (FIG. 6) along with or separate from the baseline profile data base and optionally the first profile data set although the first profile data set would normally become incorporated into a baseline profile data set under suitable classification criteria. The remarkable consistency of Gene Expression Profiles associated with a given biological condition makes it valuable to store profile data, which can be used, among other things for normative reference purposes. The normative reference can serve to indicate the degree to which a subject conforms to a given biological condition (healthy or diseased) and, alternatively or in addition, to provide a target for clinical intervention.

Selected baseline profile data sets may be also be used as a standard by which to judge manufacturing lots in terms of efficacy, toxicity, etc. Where the effect of a therapeutic agent is being measured, the baseline data set may correspond to Gene Expression Profiles taken before administration of the agent. Where quality control for a newly manufactured product is being determined, the baseline data set may correspond with a gold standard for that product. However, any suitable normalization techniques may be employed. For example, an average baseline profile data set is obtained from authentic material of a naturally grown herbal nutriceutical and compared over time and over different lots in order to demonstrate consistency, or lack of consistency, in lots of compounds prepared for release.

Calibrated Data

Given the repeatability we have achieved in measurement of gene expression, described above in connection with “Gene Expression Panels” and “gene amplification”, we conclude that where differences occur in measurement under such conditions, the differences are attributable to differences in biological condition. Thus we have found that calibrated profile data sets are highly reproducible in samples taken from the same individual under the same conditions. We have similarly found that calibrated profile data sets are reproducible in samples that are repeatedly tested. We have also found repeated instances wherein calibrated profile data sets obtained when samples from a subject are exposed ex vivo to a compound are comparable to calibrated profile data from a sample that has been exposed to a sample in vivo. We have also found, importantly, that an indicator cell line treated with an agent can in many cases provide calibrated profile data sets comparable to those obtained from in vivo or ex vivo populations of cells. Moreover, we have found that administering a sample from a subject onto indicator cells can provide informative calibrated profile data sets with respect to the biological condition of the subject including the health, disease states, therapeutic interventions, aging or exposure to environmental stimuli or toxins of the subject.

Calculation of Calibrated Profile Data Sets and Computational Aids

The calibrated profile data set may be expressed in a spreadsheet or represented graphically for example, in a bar chart or tabular form but may also be expressed in a three dimensional representation. The function relating the baseline and profile data may be a ratio expressed as a logarithm. The constituent may be itemized on the x-axis and the logarithmic scale may be on the y-axis. Members of a calibrated data set may be expressed as a positive value representing a relative enhancement of gene expression or as a negative value representing a relative reduction in gene expression with respect to the baseline.

Each member of the calibrated profile data set should be reproducible within a range with respect to similar samples taken from the subject under similar conditions. For example, the calibrated profile data sets may be reproducible within one order of magnitude with respect to similar samples taken from the subject under similar conditions. More particularly, the members may be reproducible within 50%, more particularly reproducible within 20%, and typically within 10%. In accordance with embodiments of the invention, a pattern of increasing, decreasing and no change in relative gene expression from each of a plurality of gene loci examined in the Gene Expression Panel may be used to prepare a calibrated profile set that is informative with regards to a biological condition, biological efficacy of an agent treatment conditions or for comparison to populations. Patterns of this nature may be used to identify likely candidates for a drug trial, used alone or in combination with other clinical indicators to be diagnostic or prognostic with respect to a biological condition or may be used to guide the development of a pharmaceutical or nutriceutical through manufacture, testing and marketing.

The numerical data obtained from quantitative gene expression and numerical data from calibrated gene expression relative to a baseline profile data set may be stored in databases or digital storage mediums and may retrieved for purposes including managing patient health care or for conducting clinical trials or for characterizing a drug. The data may be transferred in physical or wireless networks via the World Wide Web, email, or internet access site for example or by hard copy so as to be collected and pooled from distant geographic sites (FIG. 8).

In an embodiment of the present invention, a descriptive record is stored in a single database or multiple databases where the stored data includes the raw gene expression data (first profile data set) prior to transformation by use of a baseline profile data set, as well as a record of the baseline profile data set used to generate the calibrated profile data set including for example, annotations regarding whether the baseline profile data set is derived from a particular Signature Panel and any other annotation that facilitates interpretation and use of the data.

Because the data is in a universal format, data handling may readily be done with a computer. The data is organized so as to provide an output optionally corresponding to a graphical representation of a calibrated data set.

For example, a distinct sample derived from a subject being at least one of RNA or protein may be denoted as P_(I). The first profile data set derived from sample P_(I) is denoted M_(j), where M_(j) is a quantitative measure of a distinct RNA or protein constituent of P_(I). The record Ri is a ratio of M and P and may be annotated with additional data on the subject relating to, for example, age, diet, ethnicity, gender, geographic location, medical disorder, mental disorder, medication, physical activity, body mass and environmental exposure. Moreover, data handling may further include accessing data from a second condition database which may contain additional medical data not presently held with the calibrated profile data sets. In this context, data access may be via a computer network.

The above described data storage on a computer may provide the information in a form that can be accessed by a user. Accordingly, the user may load the information onto a second access site including downloading the information. However, access may be restricted to users having a password or other security device so as to protect the medical records contained within. A feature of this embodiment of the invention is the ability of a user to add new or annotated records to the data set so the records become part of the biological information.

The graphical representation of calibrated profile data sets pertaining to a product such as a drug provides an opportunity for standardizing a product by means of the calibrated profile, more particularly a signature profile. The profile may be used as a feature with which to demonstrate relative efficacy, differences in mechanisms of actions, etc. compared to other drugs approved for similar or different uses.

The various embodiments of the invention may be also implemented as a computer program product for use with a computer system. The product may include program code for deriving a first profile data set and for producing calibrated profiles. Such implementation may include a series of computer instructions fixed either on a tangible medium, such as a computer readable medium (for example, a diskette, CD-ROM, ROM, or fixed disk), or transmittable to a computer system via a modem or other interface device, such as a communications adapter coupled to a network. The network coupling may be for example, over optical or wired communications lines or via wireless techniques (for example, microwave, infrared or other transmission techniques) or some combination of these. The series of computer instructions preferably embodies all or part of the functionality previously described herein with respect to the system. Those skilled in the art should appreciate that such computer instructions can be written in a number of programming languages for use with many computer architectures or operating systems. Furthermore, such instructions may be stored in any memory device, such as semiconductor, magnetic, optical or other memory devices, and may be transmitted using any communications technology, such as optical, infrared, microwave, or other transmission technologies. It is expected that such a computer program product may be distributed as a removable medium with accompanying printed or electronic documentation (for example, shrink wrapped software), preloaded with a computer system (for example, on system ROM or fixed disk), or distributed from a server or electronic bulletin board over a network (for example, the Internet or World Wide Web). In addition, a computer system is further provided including derivative modules for deriving a first data set and a calibration profile data set.

The calibration profile data sets in graphical or tabular form, the associated databases, and the calculated index or derived algorithm, together with information extracted from the panels, the databases, the data sets or the indices or algorithms are commodities that can be sold together or separately for a variety of purposes as described in WO 01/25473.

Index Construction

In combination, (i) the remarkable consistency of Gene Expression Profiles with respect to a biological condition across a population and (ii) the use of procedures that provide substantially reproducible measurement of constituents in a Gene Expression Panel giving rise to a Gene Expression Profile, under measurement conditions wherein specificity and efficiencies of amplification for all constituents of the panel are substantially similar, make possible the use of an index that characterizes a Gene Expression Profile, and which therefore provides a measurement of a biological condition.

An index may be constructed using an index function that maps values in a Gene Expression Profile into a single value that is pertinent to the biological condition at hand. The values in a Gene Expression Profile are the amounts of each constituent of the Gene Expression Panel that corresponds to the Gene Expression Profile. These constituent amounts form a profile data set, and the index function generates a single value—the index—from the members of the profile data set.

The index function may conveniently be constructed as a linear sum of terms, each term being what we call a “contribution function” of a member of the profile data set. For example, the contribution function may be a constant times a power of a member of the profile data set. So the index function would have the form I=ΣC _(i) M _(i) ^(P(i)), where I is the index, M_(i) is the value of the member i of the profile data set, C_(i) is a constant, and P(i) is a power to which M_(i) is raised, the sum being formed for all integral values of i up to the number of members in the data set. We thus have a linear polynomial expression.

The values C_(i) and P(i) may be determined in a number of ways, so that the index I is informative of the pertinent biological condition. One way is to apply statistical techniques, such as latent class modeling, to the profile data sets to correlate clinical data or experimentally derived data, or other data pertinent to the biological condition. In this connection, for example, may be employed the software from Statistical Innovations, Belmont, Mass., called Latent Gold®. See the web pages at www.statisticalinnovations.com/lg/, which are hereby incorporated herein by reference.

Alternatively, other simpler modeling techniques may be employed in a manner known in the art. The index function for inflammation may be constructed, for example, in a manner that a greater degree of inflammation (as determined by the a profile data set for the Inflammation Gene Expression Profile) correlates with a large value of the index function. In a simple embodiment, therefore, each P(i) may be +1 or −1, depending on whether the constituent increases or decreases with increasing inflammation. As discussed in further detail below, we have constructed a meaningful inflammation index that is proportional to the expression ¼{IL1A}+¼{IL1B}+¼{TNF}+¼{INFG}−1/{IL10}, where the braces around a constituent designate measurement of such constituent and the constituents are a subset of the Inflammation Gene Expression Panel of Table 1.

Just as a baseline profile data set, discussed above, can be used to provide an appropriate normative reference, and can even be used to create a Calibrated profile data set, as discussed above, based on the normative reference, an index that characterizes a Gene Expression Profile can also be provided with a normative value of the index function used to create the index. This normative value can be determined with respect to a relevant population, so that the index may be interpreted in relation to the normative value. The relevant population may have in common a property that is at least one of age group, gender, ethnicity, geographic location, diet, medical disorder, clinical indicator, medication, physical activity, body mass, and environmental exposure.

As an example, the index can be constructed, in relation to a normative Gene Expression Profile for a population of healthy subjects, in such a way that a reading of approximately 1 characterizes normative Gene Expression Profiles of healthy subjects. Let us further assume that the biological condition that is the subject of the index is inflammation; a reading of 1 in this example thus corresponds to a Gene Expression Profile that matches the norm for healthy subjects. A substantially higher reading then may identify a subject experiencing an inflammatory condition. The use of 1 as identifying a normative value, however, is only one possible choice; another logical choice is to use 0 as identifying the normative value. With this choice, deviations in the index from zero can be indicated in standard deviation units (so that values lying between −1 and +1 encompass 90% of a normally distributed reference population. Since we have found that Gene Expression Profile values (and accordingly constructed indices based on them) tend to be normally distributed, the 0-centered index constructed in this manner is highly informative. It therefore facilitates use of the index in diagnosis of disease and setting objectives for treatment. The choice of 0 for the normative value, and the use of standard deviation units, for example, are illustrated in FIG. 17B, discussed below.

EXAMPLES Example 1 Acute Inflammatory Index to Assist in Analysis of Large, Complex Data Sets

In one embodiment of the invention the index value or algorithm can be used to reduce a complex data set to a single index value that is informative with respect to the inflammatory state of a subject. This is illustrated in FIGS. 1A and 1B.

FIG. 1A is entitled Source Precision Inflammation Profile Tracking of A Subject Results in a Large, Complex Data Set. The figure shows the results of assaying 24 genes from the Inflammation Gene Expression Panel (shown in Table 1) on eight separate days during the course of optic neuritis in a single male subject.

FIG. 1B shows use of an Acute Inflammation Index. The data displayed in FIG. 1A above is shown in this figure after calculation using an index function proportional to the following mathematical expression: (¼{IL1A}+¼{IL1B}+¼{TNF}+¼{INFG}−1/{IL10}).

Example 2 Use of Acute Inflammation Index or Algorithm to Monitor a Biological Condition of a Sample or a Subject

The inflammatory state of a subject reveals information about the past progress of the biological condition, future progress, response to treatment, etc. The Acute Inflammation Index may be used to reveal such information about the biological condition of a subject. This is illustrated in FIG. 2.

The results of the assay for inflammatory gene expression for each day (shown for 24 genes in each row of FIG. 1A) is displayed as an individual histogram after calculation. The index reveals clear trends in inflammatory status that may correlated with therapeutic intervention (FIG. 2).

FIG. 2 is a graphical illustration of the acute inflammation index calculated at 9 different, significant clinical milestones from blood obtained from a single patient treated medically with for optic neuritis. Changes in the index values for the Acute Inflammation Index correlate strongly with the expected effects of therapeutic intervention. Four clinical milestones have been identified on top of the Acute Inflammation Index in this figure including (1) prior to treatment with steroids, (2) treatment with IV solumedrol at 1 gram per day, (3) post-treatment with oral prednisone at 60 mg per day tapered to 10 mg per day and (4) post treatment. The data set is the same as for FIG. 1. The index is proportional to ¼{IL1A}+¼{IL1B}+¼{TNF}+¼{INFG}−1/{IL10}. As expected, the acute inflammation index falls rapidly with treatment with IV steroid, goes up during less efficacious treatment with oral prednisone and returns to the pre-treatment level after the steroids have been discontinued and metabolized completely.

Example 3

Use of the acute inflammatory index to set dose including concentrations and timing, for compounds in development or for compounds to be tested in human and non-human subjects as shown in FIG. 3. The acute inflammation index may be used as a common reference value for therapeutic compounds or interventions without common mechanisms of action. The compound that induces a gene response to a compound as indicated by the index, but fails to ameliorate a known biological conditions may be compared to a different compounds with varying effectiveness in treating the biological condition.

FIG. 3 shows the effects of single dose treatment with 800 mg of ibuprofen in a single donor as characterized by the Acute Inflammation Index. 800 mg of over-the-counter ibuprofen were taken by a single subject at Time=0 and Time=48 hr. Gene expression values for the indicated five inflammation-related gene loci were determined as described below at times=2, 4, 6, 48, 50, 56 and 96 hours. As expected the acute inflammation index falls immediately after taking the non-steroidal anti-inflammatory ibuprofen and returns to baseline after 48 hours. A second dose at T=48 follows the same kinetics at the first dose and returns to baseline at the end of the experiment at T=96.

Example 4

Use of the acute inflammation index to characterize efficacy, safety, and mode of physiological action for an agent which may be in development and/or may be complex in nature. This is illustrated in FIG. 4.

FIG. 4 shows that the calculated acute inflammation index displayed graphically for five different conditions including (A) untreated whole blood; (B) whole blood treated in vitro with DMSO, an non-active carrier compound; (C) otherwise unstimulated whole blood treated in vitro with dexamethasone (0.08 ug/ml); (D) whole blood stimulated in vitro with lipopolysaccharide, a known pro-inflammatory compound, (LPS, 1 ng/ml) and (E) whole blood treated in vitro with LPS (1 ng/ml) and dexamethasone (0.08 ug/ml). Dexamethasone is used as a prescription compound that is commonly used medically as an anti-inflammatory steroid compound. The acute inflammation index is calculated from the experimentally determined gene expression levels of inflammation-related genes expressed in human whole blood obtained from a single patient. Results of mRNA expression are expressed as Ct's in this example, but may be expressed as, e.g., relative fluorescence units, copy number or any other quantifiable, precise and calibrated form, for the genes IL1A, IL1B, TNF, IFNG and IL10. From the gene expression values, the acute inflammation values were determined algebraically according in proportion to the expression ¼{IL1A}+¼{IL1B}+¼{TNF}+¼{INFG}−1/{IL10}.

Example 5 Development and Use of Population Normative Values for Gene Expression Profiles

FIGS. 6 and 7 show the arithmetic mean values for gene expression profiles (using the 48 loci of the Inflammation Gene Expression Panel of Table 1) obtained from whole blood of two distinct patient populations. These populations are both normal or undiagnosed. The first population, which is identified as Bonfils (the plot points for which are represented by diamonds), is composed of 17 subjects accepted as blood donors at the Bonfils Blood Center in Denver, Colo. The second population is 9 donors, for which Gene Expression Profiles were obtained from assays conducted four times over a four-week period. Subjects in this second population (plot points for which are represented by squares) were recruited from employees of Source Precision Medicine, Inc., the assignee herein. Gene expression averages for each population were calculated for each of 48 gene loci of the Gene Expression Inflammation Panel. The results for loci 1-24 (sometimes referred to below as the Inflammation 48A loci) are shown in FIG. 6 and for loci 25-48 (sometimes referred to below as the Inflammation 48B loci) are shown in FIG. 7.

The consistency between gene expression levels of the two distinct populations is dramatic. Both populations show gene expressions for each of the 48 loci that are not significantly different from each other. This observation suggests that there is a “normal” expression pattern for human inflammatory genes, that a Gene Expression Profile, using the Inflammation Gene Expression Panel of Table 1 (or a subset thereof) characterizes that expression pattern, and that a population-normal expression pattern can be used, for example, to guide medical intervention for any biological condition that results in a change from the normal expression pattern.

In a similar vein, FIG. 8 shows arithmetic mean values for gene expression profiles (again using the 48 loci of the Inflammation Gene Expression Panel of Table 1) also obtained from whole blood of two distinct patient populations. One population, expression values for which are represented by triangular data points, is 24 normal, undiagnosed subjects (who therefore have no known inflammatory disease). The other population, the expression values for which are represented by diamond-shaped data points, is four patients with rheumatoid arthritis and who have failed therapy (who therefore have unstable rheumatoid arthritis).

As remarkable as the consistency of data from the two distinct normal populations shown in FIGS. 6 and 7 is the systematic divergence of data from the normal and diseased populations shown in FIG. 8. In 45 of the shown 48 inflammatory gene loci, subjects with unstable rheumatoid arthritis showed, on average, increased inflammatory gene expression (lower cycle threshold values; Ct), than subjects without disease. The data thus further demonstrate that is possible to identify groups with specific biological conditions using gene expression if the precision and calibration of the underlying assay are carefully designed and controlled according to the teachings herein.

FIG. 9, in a manner analogous to FIG. 8, shows the shows arithmetic mean values for gene expression profiles using 24 loci of the Inflammation Gene Expression Panel of Table 1) also obtained from whole blood of two distinct patient populations. One population, expression values for which are represented by diamond-shaped data points, is 17 normal, undiagnosed subjects (who therefore have no known inflammatory disease) who are blood donors. The other population, the expression values for which are represented by square-shaped data points, is 16 subjects, also normal and undiagnosed, who have been monitored over six months, and the averages of these expression values are represented by the square-shaped data points. Thus the cross-sectional gene expression-value averages of a first healthy population match closely the longitudinal gene expression-value averages of a second healthy population, with approximately 7% or less variation in measured expression value on a gene-to-gene basis.

FIG. 10 shows the shows gene expression values (using 14 loci of the Inflammation Gene Expression Panel of Table 1) obtained from whole blood of 44 normal undiagnosed blood donors (data for 10 subjects of which is shown). Again, the gene expression values for each member of the population are closely matched to those for the population, represented visually by the consistent peak heights for each of the gene loci. Other subjects of the population and other gene loci than those depicted here display results that are consistent with those shown here.

In consequence of these principles, and in various embodiments of the present invention, population normative values for a Gene Expression Profile can be used in comparative assessment of individual subjects as to biological condition, including both for purposes of health and/or disease. In one embodiment the normative values for a Gene Expression Profile may be used as a baseline in computing a “calibrated profile data set” (as defined at the beginning of this section) for a subject that reveals the deviation of such subject's gene expression from population normative values. Population normative values for a Gene Expression Profile can also be used as baseline values in constructing index functions in accordance with embodiments of the present invention. As a result, for example, an index function can be constructed to reveal not only the extent of an individual's inflammation expression generally but also in relation to normative values.

Example 6 Consistency of Expression Values, of Constituents in Gene Expression Panels, Over Time as Reliable Indicators of Biological Condition

FIG. 11 shows the expression levels for each of four genes (of the Inflammation Gene Expression Panel of Table 1), of a single subject, assayed monthly over a period of eight months. It can be seen that the expression levels are remarkably consistent over time.

FIGS. 12 and 13 similarly show in each case the expression levels for each of 48 genes (of the Inflammation Gene Expression Panel of Table 1), of distinct single subjects (selected in each case on the basis of feeling well and not taking drugs), assayed, in the case of FIG. 12 weekly over a period of four weeks, and in the case of FIG. 13 monthly over a period of six months. In each case, again the expression levels are remarkably consistent over time, and also similar across individuals.

FIG. 14 also shows the effect over time, on inflammatory gene expression in a single human subject, of the administration of an anti-inflammatory steroid, as assayed using the Inflammation Gene Expression Panel of Table 1. In this case, 24 of 48 loci are displayed. The subject had a baseline blood sample drawn in a PAX RNA isolation tube and then took a single 60 mg dose of prednisone, an anti-inflammatory, prescription steroid. Additional blood samples were drawn at 2 hr and 24 hr post the single oral dose. Results for gene expression are displayed for all three time points, wherein values for the baseline sample are shown as unity on the x-axis. As expected, oral treatment with prednisone resulted in the decreased expression of most of inflammation-related gene loci, as shown by the 2-hour post-administration bar graphs. However, the 24-hour post-administration bar graphs show that, for most of the gene loci having reduced gene expression at 2 hours, there were elevated gene expression levels at 24 hr.

Although the baseline in FIG. 14 is based on the gene expression values before drug intervention associated with the single individual tested, we know from the previous example, that healthy individuals tend toward population normative values in a Gene Expression Profile using the Inflammation Gene Expression Panel of Table 1 (or a subset of it). We conclude from FIG. 14 that in an attempt to return the inflammatory gene expression levels to those demonstrated in FIGS. 6 and 7 (normal or set levels), interference with the normal expression induced a compensatory gene expression response that over-compensated for the drug-induced response, perhaps because the prednisone had been significantly metabolized to inactive forms or eliminated from the subject.

FIG. 15, in a manner analogous to FIG. 14, shows the effect over time, via whole blood samples obtained from a human subject, administered a single dose of prednisone, on expression of 5 genes (of the Inflammation Gene Expression Panel of Table 1). The samples were taken at the time of administration (t=0) of the prednisone, then at two and 24 hours after such administration. Each whole blood sample was challenged by the addition of 0.1 ng/ml of lipopolysaccharide (a Gram-negative endotoxin) and a gene expression profile of the sample, post-challenge, was determined It can seen that the two-hour sample shows dramatically reduced gene expression of the 5 loci of the Inflammation Gene Expression Panel, in relation to the expression levels at the time of administration (t=0). At 24 hours post administration, the inhibitory effect of the prednisone is no longer apparent, and at 3 of the 5 loci, gene expression is in fact higher than at t=0, illustrating quantitatively at the molecular level the well-known rebound effect.

FIG. 16 also shows the effect over time, on inflammatory gene expression in a single human subject suffering from rheumatoid arthritis, of the administration of a TNF-inhibiting compound, but here the expression is shown in comparison to the cognate locus average previously determined (in connection with FIGS. 6 and 7) for the normal (i.e., undiagnosed, healthy) population. As part of a larger international study involving patients with rheumatoid arthritis, the subject was followed over a twelve-week period. The subject was enrolled in the study because of a failure to respond to conservative drug therapy for rheumatoid arthritis and a plan to change therapy and begin immediate treatment with a TNF-inhibiting compound. Blood was drawn from the subject prior to initiation of new therapy (visit 1). After initiation of new therapy, blood was drawn at 4 weeks post change in therapy (visit 2), 8 weeks (visit 3), and 12 weeks (visit 4) following the start of new therapy. Blood was collected in PAX RNA isolation tubes, held at room temperature for two hours and then frozen at −30° C.

Frozen samples were shipped to the central laboratory at Source Precision Medicine, the assignee herein, in Boulder, Colo. for determination of expression levels of genes in the 48-gene Inflammation Gene Expression Panel of Table 1. The blood samples were thawed and RNA extracted according to the manufacturer's recommended procedure. RNA was converted to cDNA and the level of expression of the 48 inflammatory genes was determined. Expression results are shown for 11 of the 48 loci in FIG. 16. When the expression results for the 11 loci are compared from visit one to a population average of normal blood donors from the United States, the subject shows considerable difference. Similarly, gene expression levels at each of the subsequent physician visits for each locus are compared to the same normal average value. Data from visits 2, 3 and 4 document the effect of the change in therapy. In each visit following the change in the therapy, the level of inflammatory gene expression for 10 of the 11 loci is closer to the cognate locus average previously determined for the normal (i.e., undiagnosed, healthy) population.

FIG. 17A further illustrates the consistency of inflammatory gene expression, illustrated here with respect to 7 loci of (of the Inflammation Gene Expression Panel of Table 1), in a population of 44 normal, undiagnosed blood donors. For each individual locus is shown the range of values lying within ±2 standard deviations of the mean expression value, which corresponds to 95% of a normally distributed population. Notwithstanding the great width of the confidence interval (95%), the measured gene expression value (ΔCT)—remarkably—still lies within 10% of the mean, regardless of the expression level involved. As described in further detail below, for a given biological condition an index can be constructed to provide a measurement of the condition. This is possible as a result of the conjunction of two circumstances: (i) there is a remarkable consistency of Gene Expression Profiles with respect to a biological condition across a population and (ii) there can be employed procedures that provide substantially reproducible measurement of constituents in a Gene Expression Panel giving rise to a Gene Expression Profile, under measurement conditions wherein specificity and efficiencies of amplification for all constituents of the panel are substantially similar and which therefore provides a measurement of a biological condition. Accordingly, a function of the expression values of representative constituent loci of FIG. 17A is here used to generate an inflammation index value, which is normalized so that a reading of 1 corresponds to constituent expression values of healthy subjects, as shown in the right-hand portion of FIG. 17A.

In FIG. 17B, an inflammation index value was determined for each member of a population of 42 normal undiagnosed blood donors, and the resulting distribution of index values, shown in the figure, can be seen to approximate closely a normal distribution, notwithstanding the relatively small population size. The values of the index are shown relative to a 0-based median, with deviations from the median calibrated in standard deviation units. Thus 90% of the population lies within +1 and −1 of a 0 value. We have constructed various indices, which exhibit similar behavior.

FIG. 17C illustrates the use of the same index as FIG. 17B, where the inflammation median for a normal population has been set to zero and both normal and diseased subjects are plotted in standard deviation units relative to that median. An inflammation index value was determined for each member of a normal, undiagnosed population of 70 individuals (black bars). The resulting distribution of index values, shown in FIG. 17C, can be seen to approximate closely a normal distribution. Similarly, index values were calculated for individuals from two diseased population groups, (1) rheumatoid arthritis patients treated with methotrexate (MTX) who are about to change therapy to more efficacious drugs (e.g., TNF inhibitors)(hatched bars), and (2) rheumatoid arthritis patients treated with disease modifying anti-rheumatoid drugs (DMARDS) other than MTX, who are about to change therapy to more efficacious drugs (e.g., MTX). Both populations present index values that are skewed upward (demonstrating increased inflammation) in comparison to the normal distribution. This figure thus illustrates the utility of an index to derived from Gene Expression Profile data to evaluate disease status and to provide an objective and quantifiable treatment objective. When these two populations were treated appropriately, index values from both populations returned to a more normal distribution (data not shown here).

FIG. 18 plots, in a fashion similar to that of FIG. 17A, Gene Expression Profiles, for the same 7 loci as in FIG. 17A, two different 6-subject populations of rheumatoid arthritis patients. One population (called “stable” in the figure) is of patients who have responded well to treatment and the other population (called “unstable” in the figure) is of patients who have not responded well to treatment and whose therapy is scheduled for change. It can be seen that the expression values for the stable population, lie within the range of the 95% confidence interval, whereas the expression values for the unstable population for 5 of the 7 loci are outside and above this range. The right-hand portion of the figure shows an average inflammation index of 9.3 for the unstable population and an average inflammation index of 1.8 for the stable population, compared to 1 for a normal undiagnosed population. The index thus provides a measure of the extent of the underlying inflammatory condition, in this case, rheumatoid arthritis. Hence the index, besides providing a measure of biological condition, can be used to measure the effectiveness of therapy as well as to provide a target for therapeutic intervention.

FIG. 19 thus illustrates use of the inflammation index for assessment of a single subject suffering from rheumatoid arthritis, who has not responded well to traditional therapy with methotrexate. The inflammation index for this subject is shown on the far right at start of a new therapy (a TNF inhibitor), and then, moving leftward, successively, 2 weeks, 6 weeks, and 12 weeks thereafter. The index can be seen moving towards normal, consistent with physician observation of the patient as responding to the new treatment.

FIG. 20 similarly illustrates use of the inflammation index for assessment of three subjects suffering from rheumatoid arthritis, who have not responded well to traditional therapy with methotrexate, at the beginning of new treatment (also with a TNF inhibitor), and 2 weeks and 6 weeks thereafter. The index in each case can again be seen moving generally towards normal, consistent with physician observation of the patients as responding to the new treatment.

Each of FIGS. 21-23 shows the inflammation index for an international group of subjects, suffering from rheumatoid arthritis, each of whom has been characterized as stable (that is, not anticipated to be subjected to a change in therapy) by the subject's treating physician. FIG. 21 shows the index for each of 10 patients in the group being treated with methotrexate, which known to alleviate symptoms without addressing the underlying disease. FIG. 22 shows the index for each of 10 patients in the group being treated with Enbrel (an TNF inhibitor), and FIG. 23 shows the index for each 10 patients being treated with Remicade (another TNF inhibitor). It can be seen that the inflammation index for each of the patients in FIG. 21 is elevated compared to normal, whereas in FIG. 22, the patients being treated with Enbrel as a class have an inflammation index that comes much closer to normal (80% in the normal range). In FIG. 23, it can be seen that, while all but one of the patients being treated with Remicade have an inflammation index at or below normal, two of the patients have an abnormally low inflammation index, suggesting an immunosuppressive response to this drug. (Indeed, studies have shown that Remicade has been associated with serious infections in some subjects, and here the immunosuppressive effect is quantified.) Also in FIG. 23, one subject has an inflammation index that is significantly above the normal range. This subject in fact was also on a regimen of an anti-inflammation steroid (prednisone) that was being tapered; within approximately one week after the inflammation index was sampled, the subject experienced a significant flare of clinical symptoms.

Remarkably, these examples show a measurement, derived from the assay of blood taken from a subject, pertinent to the subject's arthritic condition. Given that the measurement pertains to the extent of inflammation, it can be expected that other inflammation-based conditions, including, for example, cardiovascular disease, may be monitored in a similar fashion.

FIG. 24 illustrates use of the inflammation index for assessment of a single subject suffering from inflammatory bowel disease, for whom treatment with Remicade was initiated in three doses. The graphs show the inflammation index just prior to first treatment, and then 24 hours after the first treatment; the index has returned to the normal range. The index was elevated just prior to the second dose, but in the normal range prior to the third dose. Again, the index, besides providing a measure of biological condition, is here used to measure the effectiveness of therapy (Remicade), as well as to provide a target for therapeutic intervention in terms of both dose and schedule.

FIG. 25 shows Gene Expression Profiles with respect to 24 loci (of the Inflammation Gene Expression Panel of Table 1) for whole blood treated with Ibuprofen in vitro in relation to other non-steroidal anti-inflammatory drugs (NSAIDs). The profile for Ibuprofen is in front. It can be seen that all of the NSAIDs, including Ibuprofen share a substantially similar profile, in that the patterns of gene expression across the loci are similar. Notwithstanding these similarities, each individual drug has its own distinctive signature.

FIG. 26 illustrates how the effects of two competing anti-inflammatory compounds can be compared objectively, quantitatively, precisely, and reproducibly. In this example, expression of each of a panel of two genes (of the Inflammation Gene Expression Panel of Table 1) is measured for varying doses (0.08-250 μg/ml) of each drug in vitro in whole blood. The market leader drug shows a complex relationship between dose and inflammatory gene response. Paradoxically, as the dose is increased, gene expression for both loci initially drops and then increases in the case the case of the market leader. For the other compound, a more consistent response results, so that as the dose is increased, the gene expression for both loci decreases more consistently.

FIGS. 27 through 41 illustrate the use of gene expression panels in early identification and monitoring of infectious disease. These figures plot the response, in expression products of the genes indicated, in whole blood, to the administration of various infectious agents or products associated with infectious agents. In each figure, the gene expression levels are “calibrated”, as that term is defined herein, in relation to baseline expression levels determined with respect to the whole blood prior to administration of the relevant infectious agent. In this respect the figures are similar in nature to various figures of our below-referenced patent application WO 01/25473 (for example, FIG. 15 therein). The concentration change is shown ratiometrically, and the baseline level of 1 for a particular gene locus corresponds to an expression level for such locus that is the same, monitored at the relevant time after addition of the infectious agent or other stimulus, as the expression level before addition of the stimulus. Ratiometric changes in concentration are plotted on a logarithmic scale. Bars below the unity line represent decreases in concentration and bars above the unity line represent increases in concentration, the magnitude of each bar indicating the magnitude of the ratio of the change. We have shown in WO 01/25473 and other experiments that, under appropriate conditions, Gene Expression Profiles derived in vitro by exposing whole blood to a stimulus can be representative of Gene Expression Profiles derived in vivo with exposure to a corresponding stimulus.

FIG. 27 uses a novel bacterial Gene Expression Panel of 24 genes, developed to discriminate various bacterial conditions in a host biological system. Two different stimuli are employed: lipotechoic acid (LTA), a gram positive cell wall constituent, and lipopolysaccharide (LPS), a gram negative cell wall constituent. The final concentration immediately after administration of the stimulus was 100 ng/mL, and the ratiometric changes in expression, in relation to pre-administration levels, were monitored for each stimulus 2 and 6 hours after administration. It can be seen that differential expression can be observed as early as two hours after administration, for example, in the IFNα2 locus, as well as others, permitting discrimination in response between gram positive and gram negative bacteria.

FIG. 28 shows differential expression for a single locus, IFNG, to LTA derived from three distinct sources: S. pyogenes, B. subtilis, and S. aureus. Each stimulus was administered to achieve a concentration of 100 ng/mL, and the response was monitored at 1, 2, 4, 6, and 24 hours after administration. The results suggest that Gene Expression Profiles can be used to distinguish among different infectious agents, here different species of gram positive bacteria.

FIGS. 29 and 30 show the response of the Inflammation 48A and 48B loci respectively (discussed above in connection with FIGS. 6 and 7 respectively) in whole blood to administration of a stimulus of S. aureus and of a stimulus of E. coli (in the indicated concentrations, just after administration, of 10⁷ and 10⁶ CFU/mL respectively), monitored 2 hours after administration in relation to the pre-administration baseline. The figures show that many of the loci respond to the presence of the bacterial infection within two hours after infection.

FIGS. 31 and 32 correspond to FIGS. 29 and 30 respectively and are similar to them, with the exception that the monitoring here occurs 6 hours after administration. More of the loci are responsive to the presence of infection. Various loci, such as IL2, show expression levels that discriminate between the two infectious agents.

FIG. 33 shows the response of the Inflammation 48A loci to the administration of a stimulus of E. coli (again in the concentration just after administration of 10⁶ CFU/mL) and to the administration of a stimulus of an E. coli filtrate containing E. coli bacteria by products but lacking E. coli bacteria. The responses were monitored at 2, 6, and 24 hours after administration. It can be seen, for example, that the responses over time of loci IL1B, IL18 and CSF3 to E. coli and to E. coli filtrate are different.

FIG. 34 is similar to FIG. 33, but here the compared responses are to stimuli from E. coli filtrate alone and from E. coli filtrate to which has been added polymyxin B, an antibiotic known to bind to lipopolysaccharide (LPS). An examination of the response of IL1B, for example, shows that presence of polymyxin B did not affect the response of the locus to E. coli filtrate, thereby indicating that LPS does not appear to be a factor in the response of IL1B to E. coli filtrate.

FIG. 35 illustrates the responses of the Inflammation 48A loci over time of whole blood to a stimulus of S. aureus (with a concentration just after administration of 10⁷ CFU/mL) monitored at 2, 6, and 24 hours after administration. It can be seen that response over time can involve both direction and magnitude of change in expression. (See for example, IL5 and IL18.)

FIGS. 36 and 37 show the responses, of the Inflammation 48A and 48B loci respectively, monitored at 6 hours to stimuli from E. coli (at concentrations of 10⁶ and 10² CFU/mL immediately after administration) and from S. aureus (at concentrations of 10⁷ and 10² CFU/mL immediately after administration). It can be seen, among other things, that in various loci, such as B7 (FIG. 36), TACI, PLA2G7, and C1QA (FIG. 37), E. coli produces a much more pronounced response than S. aureus. The data suggest strongly that Gene Expression Profiles can be used to identify with high sensitivity the presence of gram negative bacteria and to discriminate against gram positive bacteria.

FIGS. 38 and 39 show the responses, of the Inflammation 48B and 48A loci respectively, monitored 2, 6, and 24 hours after administration, to stimuli of high concentrations of S. aureus and E. coli respectively (at respective concentrations of 10⁷ and 10⁶ CFU/mL immediately after administration). The responses over time at many loci involve changes in magnitude and direction. FIG. 40 is similar to FIG. 39, but shows the responses of the Inflammation 48B loci.

FIG. 41 similarly shows the responses of the Inflammation 48A loci monitored at 24 hours after administration to stimuli high concentrations of S. aureus and E. coli respectively (at respective concentrations of 10⁷ and 10⁶ CFU/mL immediately after administration). As in the case of FIGS. 20 and 21, responses at some loci, such as GRO1 and GRO2, discriminate between type of infection.

These data support our conclusion that Gene Expression Profiles with sufficient precision and calibration as described herein (1) can determine subpopulations of individuals with a known biological condition; (2) may be used to monitor the response of patients to therapy; (3) may be used to assess the efficacy and safety of therapy; and (4) may used to guide the medical management of a patient by adjusting therapy to bring one or more relevant Gene Expression Profiles closer to a target set of values, which may be normative values or other desired or achievable values. We have shown that Gene Expression Profiles may provide meaningful information even when derived from ex vivo treatment of blood or other tissue. We have also shown that Gene Expression Profiles derived from peripheral whole blood are informative of a wide range of conditions neither directly nor typically associated with blood.

Furthermore, in embodiments of the present invention, Gene Expression Profiles can also be used for characterization and early identification (including pre-symptomatic states) of infectious disease, such as sepsis. This characterization includes discriminating between infected and uninfected individuals, bacterial and viral infections, specific subtypes of pathogenic agents, stages of the natural history of infection (e.g., early or late), and prognosis. Use of the algorithmic and statistical approaches discussed above to achieve such identification and to discriminate in such fashion is within the scope of various embodiments herein.

TABLE 1 Inflammation Gene Expression Panel Symbol Name Classification Description IL1A Interleukin 1, cytokines-chemokines- Proinflammatory; constitutively alpha growth factors and alpha inducibly expressed in variety of cells. Generally cytosolic and released only during severe inflammatory disease IL1B Interleukin 1, cytokines-chemokines- Proinflammatory; constitutively beta growth factors and inducibly expressed by many cell types, secreted TNFA Tumor necrosis cytokines-chemokines- Proinflammatory, TH1, mediates factor, alpha growth factors host response to bacterial stimulus, regulates cell growth & differentiation IL6 Interleukin 6 cytokines-chemokines- Pro- and antiinflammatory activity, (interferon, beta growth factors TH2 cytokine, regulates 2) hemotopoietic system and activation of innate response IL8 Interleukin 8 cytokines-chemokines- Proinflammatory, major secondary growth factors inflammatory mediator, cell adhesion, signal transduction, cell- cell signaling, angiogenesis, synthesized by a wide variety of cell types IFNG Interferon gamma cytokines-chemokines- Pro- and antiinflammatory activity, growth factors TH1 cytokine, nonspecific inflammatory mediator, produced by activated T-cells IL2 Interleukin 2 cytokines-chemokines- T-cell growth factor, expressed by growth factors activated T-cells, regulates lymphocyte activation and differentiation; inhibits apoptosis, TH1 cytokine IL12B Interleukin 12 cytokines-chemokines- Proinflammatory; mediator of p40 growth factors innate immunity, TH1 cytokine, requires co-stimulation with IL-18 to induce IFN-g IL15 Interleukin 15 cytokines-chemokines- Proinflammatory; mediates T-cell growth factors activation, inhibits apoptosis, synergizes with IL-2 to induce IFN-g and TNF-a IL18 Interleukin 18 cytokines-chemokines- Proinflammatory, TH1, innate and growth factors aquired immunity, promotes apoptosis, requires co-stimulation with IL-1 or IL-2 to induce TH1 cytokines in T-and NK-cells IL4 Interleukin 4 cytokines-chemokines- Antiinflammatory; TH2; growth factors suppresses proinflammatory cytokines, increases expression of IL-1RN, regulates lymphocyte activation IL5 Interleukin 5 cytokines-chemokines- Eosinophil stimulatory factor; growth factors stimulates late B cell differentiation to secretion of Ig IL10 Interleukin 10 cytokines-chemokines- Antiinflammatory; TH2; growth factors suppresses production of proinflammatory cytokines IL13 Interleukin 13 cytokines-chemokines- Inhibits inflammatory cytokine growth factors production IL1RN Interleukin 1 cytokines-chemokines- IL1 receptor antagonist; receptor growth factors Antiinflammatory; inhibits binding antagonist of IL-1 to IL-1 receptor by binding to receptor without stimulating IL- 1-like activity IL18BP IL-18 Binding cytokines-chemokines- Implicated in inhibition of early Protein growth factors TH1 cytokine responses TGFB1 Transforming cytokines-chemokines- Pro- and antiinflammatory activity, growth factor, growth factors anti-apoptotic; cell-cell signaling, beta 1 can either inhibit or stimulate cell growth IFNA2 Interferon, alpha 2 cytokines-chemokines- interferon produced by growth factors macrophages with antiviral effects GRO1 GRO1 oncogene cytokines-chemokines- AKA SCYB1; chemotactic for (melanoma growth factors neutrophils growth stimulating activity, alpha) GRO2 GRO2 oncogene cytokines-chemokines- AKA MIP2, SCYB2; Macrophage growth factors inflammatory protein produced by monocytes and neutrophils TNFSF5 Tumor necrosis cytokines-chemokines- ligand for CD40; expressed on the factor (ligand) growth factors surface of T cells. It regulates B superfamily, cell function by engaging CD40 on member 5 the B cell surface TNFSF6 Tumor necrosis cytokines-chemokines- AKA FasL; Ligand for FAS factor (ligand) growth factors antigen; transduces apoptotic superfamily, 6 signals into cells CSF3 Colony cytokines-chemokines- AKA GCSF; cytokine that stimulating factor growth factors stimulates granulocyte 3 (granulocyte) development B7 B7 protein cell signaling and Regulatory protein that may be activation associated with lupus CSF2 Granulocyte cytokines-chemokines- AKA GM-CSF; Hematopoietic monocyte colony growth factors growth factor; stimulates growth stimulating factor and differentiation of hematopoietic precursor cells from various lineages, including granulocytes, macrophages, eosinophils, and erythrocytes TNFSF13B Tumor necrosis cytokines-chemokines- B cell activating factor, TNF factor (ligand) growth factors family superfamily, member 13b TACI Transmembrane cytokines-chemokines- T cell activating factor and calcium activator and growth factors cyclophilin modulator CAML interactor VEGF vascular cytokines-chemokines- Producted by monocytes endothelial growth factors growth factor ICAM1 Intercellular Cell Adhesion/Matrix Endothelial cell surface molecule; adhesion Protein regulates cell adhesion and molecule 1 trafficking, upregulated during cytokine stimulation PTGS2 Prostaglandin- Enzyme/Redox AKA COX2; Proinflammatory, endoperoxide member of arachidonic acid to synthase 2 prostanoid conversion pathway; induced by proinflammatory cytokines NOS2A Nitric oxide Enzyme/Redox AKA iNOS; produces NO which is synthase 2A bacteriocidal/tumoricidal PLA2G7 Phospholipase Enzyme/Redox Platelet activating factor A2, group VII (platelet activating factor acetylhydrolase, plasma) HMOX1 Heme oxygenase Enzyme/Redox Endotoxin inducible (decycling) 1 F3 F3 Enzyme/Redox AKA thromboplastin, Coagulation Factor 3; cell surface glycoprotein responsible for coagulation catalysis CD3Z CD3 antigen, zeta Cell Marker T-cell surface glycoprotein polypeptide PTPRC protein tyrosine Cell Marker AKA CD45; mediates T-cell phosphatase, activation receptor type, C CD14 CD14 antigen Cell Marker LPS receptor used as marker for monocytes CD4 CD4 antigen Cell Marker Helper T-cell marker (p55) CD8A CD8 antigen, Cell Marker Suppressor T cell marker alpha polypeptide CD19 CD19 antigen Cell Marker AKA Leu 12; B cell growth factor HSPA1A Heat shock cell signaling and heat shock protein 70 kDa protein 70 activation MMP3 Matrix Proteinase/Proteinase AKA stromelysin; degrades metalloproteinase 3 Inhibitor fibronectin, laminin and gelatin MMP9 Matrix Proteinase/Proteinase AKA gelatinase B; degrades metalloproteinase 9 Inhibitor extracellular matrix molecules, secreted by IL-8-stimulated neutrophils PLAU Plasminogen Proteinase/Proteinase AKA uPA; cleaves plasminogen to activator, Inhibitor plasmin (a protease responsible for urokinase nonspecific extracellular matrix degradation) SERPINE1 Serine (or Proteinase/Proteinase Plasminogen activator inhibitor- cysteine) protease Inhibitor 1/PAI-1 inhibitor, clade B (ovalbumin), member 1 TIMP1 tissue inhibitor of Proteinase/Proteinase Irreversibly binds and inhibits metalloproteinase 1 Inhibitor metalloproteinases, such as collagenase C1QA Complement Proteinase/Proteinase Serum complement system; forms component 1, q Inhibitor C1 complex with the proenzymes subcomponent, c1r and cls alpha polypeptide HLA- Major Histocompatibility Binds antigen for presentation to DRB1 histocompatibility CD4+ cells complex, class II, DR beta 1

TABLE 2 Diabetes Gene Expression Panel Symbol Name Classification Description G6PC glucose-6- Glucose-6- Catalyzes the final step in the phosphatase, phosphatase/Glycogen gluconeogenic and glycogenolytic catalytic metabolism pathways. Stimulated by glucocorticoids and strongly inhibited by insulin. Overexpression (in conjunction with PCK1 overexpression) leads to increased hepatic glucose production. GCG glucagon pancreatic/peptide Pancreatic hormone which hormone counteracts the glucose-lowering action of insulin by stimulating glycogenolysis and gluconeogenesis. Underexpression of glucagon is preferred. Glucagon-like peptide (GLP-1) proposed for type 2 diabetes treatment inhibits glucag GCGR glucagon receptor glucagon receptor Expression of GCGR is strongly upregulated by glucose. Deficiency or imbalance could play a role in NIDDM. Has been looked as a potential for gene therapy. GFPT1 glutamine- Glutamine The rate limiting enzyme for fructose-6- amidotransferase glucose entry into the hexosamine phosphate biosynthetic pathway (HBP). transaminase 1 Overexpression of GFA in muscle and adipose tissue increases products of the HBP which are thought to cause insulin resistance (possibly through defects to glucose) GYS1 glycogen synthase Transferase/Glycogen A key enzyme in the regulation of 1 (muscle) metabolism glycogen synthesis in the skeletal muscles of humans. Typically stimulated by insulin, but in NIDDM individuals GS is shown to be completely resistant to insulin stimulation (decreased activity and activation in muscle) HK2 hexokinase 2 hexokinase Phosphorylates glucose into glucose-6-phosphate. NIDDM patients have lower HK2 activity which may contribute to insulin resistance. Similar action to GCK. INS insulin Insulin receptor ligand Decreases blood glucose concentration and accelerates glycogen synthesis in the liver. Not as critical in NIDDM as in IDDM. IRS1 insulin receptor signal Positive regulation of insulin substrate 1 transduction/transmembrane action. This protein is activated receptor protein when insulin binds to insulin receptor - binds 85-kDa subunit of PI 3-K. decreased in skeletal muscle of obese humans. PCK1 Phosphoenolpyruvate rate-limiting Rate limiting enzyme for carboxykinase 1 gluconeogenic enzyme gluconeogenesis - plays a key role in the regulation of hepatic glucose output by insulin and glucagon. Overexpression in the liver results in increased hepatic glucose production and hepatic insulin resistance to glycogen synthe PIK3R1 phosphoinositide- regulatory enzyme Positive regulation of insulin 3-kinase, action. Docks in IRS proteins and regulatory subunit, Gab1 - activity is required for polypeptide 1 (p85 insulin stimulated translocation of alpha) glucose transporters to the plasma membrane and activation of glucose uptake. PPARG peroxisome transcription The primary pharmacological proliferator- factor/Ligand- target for the treatment of insulin activated receptor, dependent nuclear resistance in NIDDM. Involved in gamma receptor glucose and lipid metabolism in skeletal muscle. PRKCB1 protein kinase C, protein kinase C/protein Negative regulation of insulin beta 1 phosphorylation action. Activated by hyperglycemia - increases phosphorylation of IRS-1 and reduces insulin receptor kinase activity. Increased PKC activation may lead to oxidative stress causing overexpression of TGF- beta and fibronectin SLC2A2 solute carrier glucose transporter Glucose transporters expressed family 2 uniquely in b-cells and liver. (facilitated glucose Transport glucose into the b-cell. transporter), Typically underexpressed in member 2 pancreatic islet cells of individuals with NIDDM. SLC2A4 solute carrier glucose transporter Glucose transporter protein that is family 2 final mediator in insulin-stimulated (facilitated glucose glucose uptake (rate limiting for transporter), glucose uptake). Underexpression member 4 not important, but overexpression in muscle and adipose tissue consistently shown to increase glucose transport. TGFB1 transforming Transforming growth Regulated by glucose - in NIDDM growth factor, beta 1 factor beta receptor individuals, overexpression (due to ligand oxidative stress—see PKC) promotes renal cell hypertrophy leading to diabetic nephropathy. TNF tumor necrosis cytokine/tumor necrosis Negative regulation of insulin factor factor receptor ligand action. Produced in excess by adipose tissue of obese individuals - increases IRS-1 phosphorylation and decreases insulin receptor kinase activity.

TABLE 3 Prostate Gene Expression Panel Symbol Name Classification Description ABCC1 ATP-binding membrane transporter AKA MRP1, ABC29: cassette, sub- Multispecific organic anion family C, membrane transporter; member 1 overexpression confers tissue protection against a wide variety of xenobiotics due to their removal from the cell. ACPP Acid phosphatase AKA PAP: Major phosphatase of phosphatase, the prostate; synthesized under prostate androgen regulation; secreted by the epithelial cells of the prostrate BCL2 B-cell CLL/ apoptosis Inhibitor-cell Blocks apoptosis by interfering lymphoma 2 cycle control- with the activation of caspases oncogenesis BIRC5 Baculoviral IAP apoptosis Inhibitor AKA Survivin; API4: May repeat-containing 5 counteract a default induction of apoptosis in G2/M phase of cell cycle; associates with microtubules of the mitotic spindle during apoptosis CDH1 Cadherin 1, type cell-cell adhesion/ AKA ECAD, UVO: Calcium ion- 1, E-cadherin interaction dependent cell adhesion molecule that mediates cell to cell interactions in epithelial cells CDH2 Cadherin 2, type cell-cell adhesion/ AKA NCAD, CDHN: Calcium- 1, N-cadherin interaction dependent glycoprotein that mediates cell-cell interactions; may be involved in neuronal recognition mechanism CDKN2A Cyclin-dependent cell cycle control- AKA p16, MTS1, INK4: Tumor kinase inhibitor tumor suppressor suppressor gene involved in a 2A variety of malignancies; arrests normal diploid cells in late G1 CTNNA1 Catenin, alpha 1 cell adhesion Binds cadherins and links them with the actin cytoskeleton FOLH1 Folate Hydrolase hydrolase AKA PSMA, GCP2: Expressed in normal and neoplastic prostate cells; membrane bound glycoprotein; hydrolyzes folate and is an N-acetylated a-linked acidic dipeptidase GSTT1 Glutathione-S- Catalyzes the conjugation of Transferase, theta 1 metabolism reduced glutathione to a wide number of exogenous and endogenous hydrophobic electrophiles; has an important role in human carcinogenesis HMGIY High mobility DNA binding- Potential oncogene with MYC group protein, transcriptional binding site at promoter region; isoforms I and Y regulation-oncogene involved in the transcription regulation of genes containing or in close proximity to a + t-rich regions HSPA1A Heat shock 70 kD cell signalling and AKA HSP-70, HSP70-1: protein 1A activation Molecular chaperone, stabilizes AU rich mRNA IGF1R Insulin-like cytokines-chemokines- Mediates insulin stimulated DNA growth factor 1 growth factors synthesis; mediates IGF1 receptor stimulated cell proliferation and differentiation IL6 Interleukin 6 cytokines-chemokines- Pro- and anti-inflammatory growth factors activity, TH2 cytokine, regulates hematopoiesis, activation of innate response, osteoclast development; elevated in sera of patients with metastatic cancer IL8 Interleukin 8 cytokines-chemokines- AKA SCYB8, MDNCF: growth factors Proinflammatory chemokine; major secondary inflammatory mediator resulting in cell adhesion, signal transduction, cell-cell signaling; regulates angiogenesis in prostate cancer KAI1 Kangai 1 tumor suppressor AKA SAR2, CD82, ST6: suppressor of metastatic ability of prostate cancer cells KLK2 Kallikrein 2, protease-kallikrein AKA hGK-1: Glandular kallikrein; prostatic expression restricted mainly to the prostate. KLK3 Kallikrein 3 protease-kallikrein AKA PSA: Kallikrein-like protease which functions normally in liquefaction of seminal fluid. Elevated in prostate cancer. KRT19 Keratin 19 structural protein- AKA K19: Type I epidermal differentiation keratin; may form intermediate filaments KRT5 Keratin 5 structural protein- AKA EBS2: 58 kD Type II keratin differentiation co-expressed with keratin 14, a 50 kD Type I keratin, in stratified epithelium. KRT5 expression is a hallmark of mitotically active keratinocytes and is the primary structural component of the 10 nm intermediate filaments of the mitotic epidermal basal cells. KRT8 Keratin 8 structural protein- AKA K8, CK8: Type II keratin; differentiation coexpressed with Keratin 18; involved in intermediate filament formation LGALS8 Lectin, cell adhesion-growth AKA PCTA-1: binds to beta Galactoside- and differentiation galactoside; involved in biological binding soluble 8 processes such as cell adhesion, cell growth regulation, inflammation, immunomodulation, apoptosis and metastasis MYC V-myc avian transcription factor- Transcription factor that promotes myelocytomatosis oncogene cell proliferation and viral oncogene transformation by activating homolog growth-promoting genes; may also repress gene expression NRP1 Neuropilin 1 cell adhesion AKA NRP, VEGF165R: A novel VEGF receptor that modulates VEGF binding to KDR (VEGF receptor) and subsequent bioactivity and therefore may regulate VEGF-induced angiogenesis; calcium-independent cell adhesion molecule that function during the formation of certain neuronal circuits PART1 Prostate Exhibits increased expression in androgen- LNCaP cells upon exposure to regulated androgens transcript 1 PCA3 Prostate cancer AKA DD3: prostate specific; antigen 3 highly expressed in prostate tumors PCANAP7 Prostate cancer AKA IPCA7: unknown function; associated protein 7 co-expressed with known prostate cancer genes PDEF Prostate transcription factor Acts as an androgen-independent epithelium transcriptional activator of the PSA specific Ets promoter; directly interacts with transcription the DNA binding domain of factor androgen receptor and enhances androgen-mediated activation of the PSA promoter PLAU Urokinase-type proteinase AKA UPA URK: cleaves plasminogen plasminogen to plasmin activator POV1 Prostate cancer RNA expressed selectively in overexpressed prostate tumor samples gene 1 PSCA Prostate stem cell antigen Prostate-specific cell surface antigen antigen expressed strongly by both androgen-dependent and - independent tumors PTGS2 Prostaglandin- cytokines-chemokines- AKA COX-2: Proinflammatory; endoperoxide growth factors member of arachidonic acid to synthase 2 prostanoid conversion pathway SERPINB5 Serine proteinase proteinase inhibitor- AKA Maspin, PI5: Protease inhibitor, clade B, tumor suppressor Inhibitor; Tumor suppressor, member 5 especially for metastasis. SERPINE1 Serine (or proteinase inhibitor AKA PAI1: regulates fibrinolysis; cystein) inhibits PLAU proteinase inhibitor, clade E, member 1 STAT3 Signal transcription factor AKA APRF: Transcription factor transduction and for acute phase response genes; activator of rapidly activated in response to transcription 3 certain cytokines and growth factors; binds to IL6 response elements TERT Telomerase AKA TCS1, EST2: reverse Ribonucleoprotein which in vitro transcriptase recognizes a single-stranded G- rich telomere primer and adds multiple telomeric repeats to its 3- prime end by using an RNA template TGFB1 Transforming cytokines-chemokines- AKA DPD1, CED: Pro- and growth factor, growth factors antiinflammatory activity; anti- beta 1 apoptotic; cell-cell signaling, can either inhibit or stimulate cell growth TNF Tumor necrosis cytokines-chemokines- AKA TNF alpha: Proinflammatory factor, member 2 growth factors cytokine that is the primary mediator of immune response and regulation, associated with TH1 responses, mediates host response to bacterial stimuli, regulates cell growth & differentiation TP53 Tumor protein 53 DNA binding protein- AKA P53: Activates expression of cell cycle-tumor genes that inhibit tumor growth suppressor and/or invasion; involved in cell cycle regulation (required for growth arrest at G1); inhibits cell growth through activation of cell- cycle arrest and apoptosis VEGF Vascular cytokines-chemokines- AKA VPF: Induces vascular Endothelial growth factors permeability, endothelial cell Growth Factor proliferation, angiogenesis

TABLE 4 Skin Response Gene Expression Panel Symbol Name Classification Description BAX BCL2 associated apoptosis induction Accelerates programmed cell death X protein germ cell development by binding to and antagonizing the apoptosis repressor BCL2; may induce caspase activation BCL2 B-cell apoptosis inhibitor- Integral mitochondrial membrane CLL-lymphoma 2 cycle control- protein that blocks the apoptotic oncogenesis death of some cells such as lymphocytes; constitutive expression of BCL2 thought to be cause of follicular lymphoma BSG Basignin signal transduction- Member of Ig superfamily; tumor peripheral plasma cell-derived collagenase membrane protein stimulatory factor; stimulates matrix metalloproteinase synthesis in fibroblasts COL7A1 Type VII collagen-differentiation- alpha 1 subunit of type VII collagen, alpha 1 extracellular matrix collagen; may link collagen fibrils to the basement membrane CRABP2 Cellular Retinoic retinoid binding-signal Low molecular weight protein Acid Binding transduction- highly expressed in skin; thought Protein transcription regulation to be important in RA-mediated regulation of skin growth & differentiation CTGF Connective insulin-like growth Member of family of peptides Tissue Growth factor-differentiation- including serum-induced Factor wounding response immediate early gene products expressed after induction by growth factors; overexpressed in fibrotic disorders DUSP1 Dual Specificity oxidative stress Induced in human skin fibroblasts Phosphatase response-tyrosine by oxidative/heat stress & growth phosphatase factors; de-phosphorylates MAP kinase erk2; may play a role in negative regulation of cellular proliferation FGF7 Fibroblast growth growth factor- aka KGF; Potent mitogen for factor 7 differentiation- epithelial cells; induced after skin wounding response- injury signal transduction FN1 Fibronectin cell adhesion-motility- Major cell surface glycoprotein of signal transduction many fibroblast cells; thought to have a role in cell adhesion, morphology, wound healing & cell motility FOS v-fos FBJ murine transcription factor- Proto-oncoprotein acting with osteosarcoma inflammatory response- JUN, stimulates transcription of virus oncogene cell growth & genes with AP-1 regulatory sites; homolog maintanence in some cases FOS expression is associated with apototic cell death GADD45A Growth Arrest cell cycle-DNA repair- Transcriptionally induced and DNA- apoptosis following stressful growth arrest damage- conditions & treatment with DNA inducible alpha damaging agents; binds to PCNA affecting it's interaction with some cell division protein kinase GRO1 GRO1 oncogene cytokines-chemokines- AKA SCYB1; chemotactic for (melanoma growth factors neutrophils growth stimulating activity, alpha) HMOX1 Heme Oxygenase 1 metabolism- Essential enzyme in heme endoplasmic reticulum catabolism; HMOX1 induced by its substrate heme & other substances such as oxidizing agents & UVA ICAM1 Intercellular Cell Adhesion/Matrix Endothelial cell surface molecule; adhesion Protein regulates cell adhesion and molecule 1 trafficking, upregulated during cytokine stimulation IL1A Interleukin 1, cytokines-chemokines- Proinflammatory; constitutively alpha growth factors and inducibly expressed in variety of cells. Generally cytosolic and released only during severe inflammatory disease IL1B Interleukin 1, cytokines-chemokines- Proinflammatory; constitutively beta growth factors and inducibly expressed by many cell types, secreted IL8 Interleukin 8 cytokines-chemokines- Proinflammatory, major secondary growth factors inflammatory mediator, cell adhesion, signal transduction, cell- cell signaling, angiogenesis, synthesized by a wide variety of cell types IVL Ivolucrin structural protein- Component of the keratinocyte peripheral plasma crosslinked envelope; first appears membrane protein in the cytosol becoming crosslinked to membrane proteins by transglutaminase JUN v-jun avian transcription factor- Proto-oncoprotein; component of sarcoma virus 17 DNA binding transcription factor AP-1 that oncogene interacts directly with target DNA homolog sequences to regulate gene expression KRT14 Keratin 14 structural protein- Type I keratin; associates with differentiation-cell shape keratin 5; component of intermediate filaments; several autosomal dominant blistering skin disorders caused by gene defects KRT16 Keratin 16 structural protein- Type I keratin; component of differentiation-cell shape intermediate filaments; induced in skin conditions favoring enhanced proliferation or abnormal differentiation KRT5 Keratin 5 structural protein- Type II intermediate filament chain differentiation-cell shape expessed largely in stratified epithelium; hallmark of mitotically active keratinocytes MAPK8 Mitogen kinase-stress response- aka JNK1; mitogen activated Activated Protein signal transduction protein kinase regulates c-Jun in Kinase 8 response to cell stress; UV irradiation of skin activates MAPK8 MMP1 Matrix Proteinase/Proteinase aka Collagenase; cleaves collagens Metalloproteinase 1 Inhibitor types I-III; plays a key role in remodeling occuring in both normal & diseased conditions; transcriptionally regulated by growth factors, hormones, cytokines & cellular transformation MMP2 Matrix Proteinase/Proteinase aka Gelatinase; cleaves collagens Metalloproteinase 2 Inhibitor types IV, V, VII and gelatin type I; produced by normal skin fibroblasts; may play a role in regulation of vascularization & the inflammatory response MMP3 Matrix Proteinase/Proteinase aka Stromelysin; degrades Metalloproteinase 3 Inhibitor fibronectin, laminin, collagens III, IV, IX, X, cartilage proteoglycans, thought to be involved in wound repair; progression of atherosclerosis & tumor initiation; produced predominantly by connective tissue cells MMP9 Matrix Proteinase/Proteinase AKA gelatinase B; degrades metalloproteinase 9 Inhibitor extracellular matrix molecules, secreted by IL-8-stimulated neutrophils NR1I2 Nuclear receptor Transcription activation aka PAR2; Member of nuclear subfamily 1 factor-signal hormone receptor family of ligand- transduction-xenobiotic activated transcription factors; metabolism activates transcription of cytochrome P-450 genes PCNA Proliferating Cell DNA binding-DNA Required for both DNA replication Nuclear Antigen replication-DNA repair- & repair; processivity factor for cell proliferation DNA polymerases delta and epsilon PI3 Proteinase proteinase inhibitor- aka SKALP; Proteinase inhibitor inhibitor 3 skin protein binding- found in epidermis of several derived extracellular matrix inflammatory skin diseases; it's expression can be used as a marker of skin irritancy PLAU Plasminogen Proteinase/Proteinase AKA uPA; cleaves plasminogen to activator, Inhibitor plasmin (a protease responsible for urokinase nonspecific extracellular matrix degradation) PTGS2 Prostaglandin- Enzyme/Redox aka COX2; Proinflammatory, endoperoxide member of arachidonic acid to synthase 2 prostanoid conversion pathway; induced by proinflammatory cytokines S100A7 S100 calcium- calcium binding- Member of S100 family of calcium binding protein 7 epidermal differentiation binding proteins; localized in the cytoplasm &/or nucleus of a wide range of cells; involved in the regulation of cell cycle progression & differentiation; markedly overexpressed in skin lesions of psoriatic patients TGFB1 Transforming cytokines-chemokines- Pro- and antiinflammatory activity, growth factor, growth factors anti-apoptotic; cell-cell signaling, beta can either inhibit or stimulate cell growth TIMP1 Tissue Inhibitor metalloproteinases Member of TIMP family; natural of Matrix inhibitor-ECM inhibitors of matrix Metalloproteinase 1 maintenance-positive metalloproteinases; control cell proliferation transcriptionally induced by cytokines & hormones; mediates erythropoeisis in vitro TNF Tumor necrosis cytokines-chemokines- Proinflammatory, TH1, mediates factor, alpha growth factors host response to bacterial stimulus, regulates cell growth & differentiation TNFSF6 Tumor necrosis ligand-apoptosis aka FASL; Apoptosis antigen factor (ligand) induction-signal ligand 1 is the ligand for FAS; superfamily, transduction interaction of FAS with its ligand member 6 is critical in triggering apoptosis of some types of cells such as lymphocytes; defects in protein may be related to some cases of SLE TP53 tumor protein p53 transcription factor- Tumor protein p53, a nuclear DNA binding-tumor protein, plays a role in regulation suppressor-DNA of cell cycle; binds to DNA p53 recombination/repair binding site and activates expression of downstream genes that inhibit growth and/or invasion of tumor VEGF vascular cytokines-chemokines- Producted by monocytes endothelial growth factor growth factor

TABLE 5 Liver Metabolism and Disease Gene Expression Panel Symbol Name Classification Description ABCC1 ATP-binding Liver Health Indicator AKA Multidrug resistance protein cassette, sub- 1; AKA CFTR/MRP; multispecific family C, member 1 organic anion membrane transporter; mediates drug resistance by pumping xenobiotics out of cell AHR Aryl hydrocarbon Metabolism Increases expression of xenobiotic receptor Receptor/Transcription metabolizing enzymes (ie P450) in Factor response to binding of planar aromatic hydrocarbons ALB Albumin Liver Health Indicator Carrier protein found in blood serum, synthesized in the liver, downregulation linked to decreased liver function/health COL1A1 Collagen, type 1, Tissue Remodelling AKA Procollagen; extracellular alpha 1 matrix protein; implicated in fibrotic processes of damaged liver CYP1A1 Cytochrome P450 Metabolism Enzyme Polycyclic aromatic hydrocarbon 1A1 metabolism; monooxygenase CYP1A2 Cytochrome P450 Metabolism Enzyme Polycyclic aromatic hydrocarbon 1A2 metabolism; monooxygenase CYP2C19 Cytochrome P450 Metabolism Enzyme Xenobiotic metabolism; 2C19 monooxygenase CYP2D6 Cytochrome P450 Metabolism Enzyme Xenobiotic metabolism; 2D6 monooxygenase CYP2E Cytochrome P450 Metabolism Enzyme Xenobiotic metabolism; 2E1 monooxygenase; catalyzes formation of reactive intermediates from small organic molecules (i.e. ethanol, acetaminophen, carbon tetrachloride) CYP3A4 Cytochrome P450 Metabolism Enzyme Xenobiotic metabolism; broad 3A4 catalytic specificity, most abundantly expressed liver P450 EPHX1 Epoxide hydrolase Metabolism Enzyme Catalyzes hydrolysis of reactive 1, microsomal epoxides to water soluble (xenobiotic) dihydrodiols FAP Fibroblast Liver Health Indicator Expressed in cancer stroma and activation protein, wound healing GST Glutathione S- Metabolism Enzyme Catalyzes glutathione conjugation transferase to metabolic substrates to form more water-soluble, excretable compounds; primer-probe set nonspecific for all members of GST family GSTA1 Glutathione S- Metabolism Enzyme Catalyzes glutathione conjugation and A2 transferase 1A1/2 to metabolic substrates to form more water-soluble, excretable compounds GSTM1 Glutathione S- Metabolism Enzyme Catalyzes glutathione conjugation transferase M1 to metabolic substrates to form more water-soluble, excretable compounds KITLG KIT ligand Growth Factor AKA Stem cell factor (SCF); mast cell growth factor, implicated in fibrosis/cirrhosis due to chronic liver inflammation LGALS3 Lectin, Liver Health Indicator AKA galectin 3; Cell growth galactoside- regulation binding, soluble, 3 NR1I2 Nuclear receptor Metabolism AKA Pregnane X receptor (PXR); subfamily 1, Receptor/Transcription heterodimer with retinoid X group I, family 2 Factor receptor forms nuclear transcription factor for CYP3A4 NR1I3 Nuclear receptor Metabolism AKA Constitutive androstane subfamily 1, Receptor/Transcription receptor beta (CAR); heterodimer group I, family 3 Factor with retinoid X receptor forms nuclear transcription factor; mediates P450 induction by phenobarbital-like inducers. ORM1 Orosomucoid 1 Liver Health Indicator AKA alpha 1 acid glycoprotein (AGP), acute phase inflammation protein PPARA Peroxisome Metabolism Receptor Binds peroxisomal proliferators (ie proliferator fatty acids, hypolipidemic drugs) activated receptor α & controls pathway for beta- oxidation of fatty acids SCYA2 Small inducible Cytokine/Chemokine AKA Monocyte chemotactic cytokine A2 protein 1 (MCP1); recruits monocytes to areas of injury and infection, upregulated in liver inflammation UCP2 Uncoupling Liver Health Indicator Decouples oxidative protein 2 phosphorylation from ATP synthesis, linked to diabetes, obesity UGT UDP- Metabolism Enzyme Catalyzes glucuronide conjugation Glucuronosyltransferase to metabolic substrates, primer- probe set nonspecific for all members of UGT1 family

TABLE 6 Endothelial Gene Expression Panel Symbol Name Classification Description ADAMTS1 Disintegrin-like Protease AKA METH1; Inhibits endothelial and cell proliferation; may inhibit metalloprotease angiogenesis; expression may be (reprolysin type) associated with development of with cancer cachexia. thrombospondin type 1 motif, 1 CLDN14 Claudin 14 AKA DFNB29; Component of tight junction strands ECE1 Endothelin Metalloprotease Cleaves big endothelin 1 to converting endothelin 1 enzyme 1 EDN1 Endothelin 1 Peptide hormone AKA ET1; Endothelium-derived peptides; potent vasoconstrictor EGR1 Early growth Transcription factor AKA NGF1A; Regulates the response 1 transcription of genes involved in mitogenesis and differentiation FLT1 Fms-related AKA VEGFR1; FRT; Receptor for tyrosine kinase 1 VEGF; involved in vascular (vascular development and regulation of endothelial vascular permeability growth factor/vascular permeability factor receptor) GJA1 gap junction AKA CX43; Protein component of protein, alpha 1, gap junctions; major component of 43 kD gap junctions in the heart; may be important in synchronizing heart contractions and in embryonic development GSR Glutathione Oxidoreductase AKA GR; GRASE; Maintains high reductase 1 levels of reduced glutathione in the cytosol HIF1A Hypoxia- Transcription factor AKA MOP1; ARNT interacting inducible factor protein; mediates the transcription 1, alpha subunit of oxygen regulated genes; induced by hypoxia HMOX1 Heme oxygenase Redox Enzyme AKA HO1; Essential for heme (decycling) 1 catabolism, cleaves heme to form biliverdin and CO; endotoxin inducible ICAM1 Intercellular Cell Adhesion/Matrix Endothelial cell surface molecule; adhesion Protein regulates cell adhesion and molecule 1 trafficking, upregulated during cytokine stimulation IGFBP3 Insulin-like AKA IBP3; Expressed by vascular growth factor endothelial cells; may influence binding protein 3 insulin-like growth factor activity IL15 Interleukin 15 cytokines-chemokines- Proinflammatory; mediates T-cell growth factors activation, inhibits apoptosis, synergizes with IL-2 to induce IFN-g and TNF-a IL1B Interleukin 1, cytokines-chemokines- Proinflammatory; constitutively beta growth factors and inducibly expressed by many cell types, secreted IL8 Interleukin 8 cytokines-chemokines- Proinflammatory, major secondary growth factors inflammatory mediator, cell adhesion, signal transduction, cell- cell signaling, angiogenesis, synthesized by a wide variety of cell types MAPK1 mitogen- Transferase AKA ERK2; May promote entry activated protein into the cell cycle, growth factor kinase 1 responsive NFKB1 Nuclear Factor Transcription Factor AKA KBF1, EBP1; Transcription kappa B factor that regulates the expression of infolammatory and immune genes; central role in Cytokine induced expression of E-selectin NOS2A Nitric oxide Enzyme/Redox AKA iNOS; produces NO which is synthase 2A bacteriocidal/tumoricidal NOS3 Endothelial Nitric AKA ENOS, CNOS; Synthesizes Oxide Synthase nitric oxide from oxygen and arginine; nitric oxide is implicated in vascular smooth muscle relaxation, vascular endothelial growth factor induced angiogenesis, and blood clotting through the activation of platelets PLAT Plasminogen Protease AKA TPA; Converts plasminogin activator, tissue to plasmin; involved in fibrinolysis and cell migration PTGIS Prostaglandin I2 Isomerase AKA PGIS; PTGI; CYP8; (prostacyclin) CYP8A1; Converts prostaglandin synthase h2 to prostacyclin (vasodilator); cytochrome P450 family; imbalance of prostacyclin may contribute to myocardial infarction, stroke, atherosclerosis PTGS2 Prostaglandin- Enzyme/Redox AKA COX2; Proinflammatory, endoperoxide member of arachidonic acid to synthase 2 prostanoid conversion pathway; induced by proinflammatory cytokines PTX3 pentaxin-related AKA TSG-14; Pentaxin 3; Similar gene, rapidly to the pentaxin subclass of induced by IL-1 inflammatory acute-phase proteins; beta novel marker of inflammatory reactions SELE selectin E Cell Adhesion AKA ELAM; Expressed by (endothelial cytokine-stimulated endothelial adhesion cells; mediates adhesion of molecule 1) neutrophils to the vascular lining SERPINE1 Serine (or Proteinase Inhibitor AKA PAI1; Plasminogen activator cysteine) protease inhibitor type 1; interacts with inhibitor, clade B tissue plasminogen activator to (ovalbumin), regulate fibrinolysis member 1 TEK tyrosine kinase, Transferase Receptor AKA TIE2, VMCM; Receptor for endothelial angiopoietin-1; may regulate endothelial cell proliferation and differentiation; involved in vascular morphogenesis; TEK defects are associated with venous malformations VCAM1 vascular cell Cell Adhesion/Matrix AKA L1CAM; CD106; INCAM- adhesion Protein 100; Cell surface adhesion molecule 1 molecule specific for blood leukocytes and some tumor cells; mediates signal transduction; may be linked to the development of atherosclerosis, and rheumatoid arthritis VEGF Vascular Growth factor AKA VPF; Induces vascular Endothelial permeability and endothelial cell Growth Factor growth; associated with angiogenesis

TABLE 7 Cell Health and Apoptosis Gene Expression Panel Symbol Name Classification Description ABL1 V-abl Abelson oncogene Cytoplasmic and nuclear protein murine tyrosine kinase implicated in cell leukemia viral differentiation, division, adhesion oncogene and stress response. Alterations of homolog 1 ABL1 lead to malignant transformations. APAF1 Apoptotic protease activator Cytochrome c binds to APAF1, Protease triggering activation of CASP3, Activating leading to apoptosis. May also Factor 1 facilitate procaspase 9 autoactivation. BAD BCL2 Agonist membrane protein Heterodimerizes with BCLX and of Cell Death counters its death repressor activity. This displaces BAX and restores its apoptosis-inducing activity. BAK1 BCL2- membrane protein In the presence of an appropriate antagonist/killer 1 stimulus BAK1 accelerates programmed cell death by binding to, and antagonizing the repressor BCL2 or its adenovirus homolog e1b 19k protein. BAX BCL2- membrane protein Accelerates apoptosis by binding associated X to, and antagonizing BCL2 or its protein adenovirus homolog e1b 19k protein. It induces the release of cytochrome c and activation of CASP3 BCL2 B-cell membrane protein Interferes with the activation of CLL/lymphoma 2 caspases by preventing the release of cytochrome c, thus blocking apoptosis. BCL2L1 BCL2-like 1 membrane protein Dominant regulator of apoptotic (long form) cell death. The long form displays cell death repressor activity, whereas the short isoform promotes apoptosis. BCL2L1 promotes cell survival by regulating the electrical and osmotic homeostasis of mitochondria. BID BH3- Induces ice-like proteases and Interacting apoptosis. Counters the protective Death Domain effect of bcl-2 (by similarity). Agonist Encodes a novel death agonist that heterodimerizes with either agonists (BAX) or antagonists (BCL2). BIK BCL2- Accelerates apoptosis. Binding to Interacting the apoptosis repressors BCL2L1, Killer bhrfl, BCL2 or its adenovirus homolog e1b 19k protein suppresses this death-promoting activity. BIRC2 Baculoviral apoptosis suppressor May inhibit apoptosis by IAP Repeat- regulating signals required for Containing 2 activation of ICE-like proteases. Interacts with TRAF1 and TRAF2. Cytoplasmic BIRC3 Baculoviral apoptosis suppressor Apoptotic suppressor. Interacts IAP Repeat- with TRAF1 and Containing 3 TRAF2.Cytoplasmic BIRC5 Survivin apoptosis suppressor Inhibits apoptosis. Inhibitor of CASP3 and CASP7. Cytoplasmic CASP1 Caspase 1 proteinase Activates IL1B; stimulates apoptosis CASP3 Caspase 3 proteinase Involved in activation cascade of caspases responsible for apoptosis- cleaves CASP6, CASP7, CASP9 CASP9 Caspase 9 proteinase Binds with APAF1 to become activated; cleaves and activates CASP3 CCNA2 Cyclin A2 cyclin Drives cell cycle at G1/S and G2/M phase; interacts with cdk2 and cdc2 CCNB1 Cyclin B1 cyclin Drives cell cycle at G2/M phase; complexes with cdc2 to form mitosis promoting factor CCND1 Cyclin D1 cyclin Controls cell cycle at G1/S (start) phase; interacts with cdk4 and cdk6; has oncogene function CCND3 Cyclin D3 cyclin Drives cell cycle at G1/S phase; expression rises later in G1 and remains elevated in S phase; interacts with cdk4 and cdk6 CCNE1 Cyclin E1 cyclin Drives cell cycle at G1/S transition; major downstream target of CCND1; cdk2-CCNE1 activity required for centrosome duplication during S phase; interacts with RB cdk2 Cyclin- kinase Associated with cyclins A, D and dependent E; activity maximal during S phase kinase 2 and G2; CDK2 activation, through caspase-mediated cleavage of CDK inhibitors, may be instrumental in the execution of apoptosis following caspase activation cdk4 Cyclin- kinase cdk4 and cyclin-D type complexes dependent are responsible for cell kinase 4 proliferation during G1; inhibited by CDKN2A (p16) CDKN1A Cyclin- tumor suppressor May bind to and inhibit cyclin- Dependent dependent kinase activity, Kinase preventing phosphorylation of Inhibitor 1A critical cyclin-dependent kinase (p21) substrates and blocking cell cycle progression; activated by p53; tumor suppressor function CDKN2B Cyclin- tumor suppressor Interacts strongly with cdk4 and Dependent cdk6; role in growth regulation but Kinase limited role as tumor suppressor Inhibitor 2B (p15) CHEK1 Checkpoint, S. pombe Involved in cell cycle arrest when DNA damage has occurred, or unligated DNA is present; prevents activation of the cdc2-cyclin b complex DAD1 Defender membrane protein Loss of DAD1 protein triggers Against Cell apoptosis Death DFFB DNA nuclease Induces DNA fragmentation and Fragmentation chromatin condensation during Factor, 40-KD, apoptosis; can be activated by Beta Subunit CASP3 FADD Fas co-receptor Apoptotic adaptor molecule that (TNFRSF6)- recruits caspase-8 or caspase-10 to associated via the activated fas (cd95) or tnfr-1 death domain receptors; this death-inducing signalling complex performs CASP8 proteolytic activation GADD45A Growth arrest regulator of DNA repair Stimulates DNA excision repair in and DNA vitro and inhibits entry of cells into damage S phase; binds PCNA inducible, alpha K-ALPHA-1 Alpha Tubulin, microtubule peptide Major constituent of microtubules; ubiquitous binds 2 molecules of GTP MADD MAP-kinase co-receptor Associates with TNFR1 through a activating death death domain-death domain domain interaction; Overexpression of MADD activates the MAP kinase ERK2, and expression of the MADD death domain stimulates both the ERK2 and JNK1 MAP kinases and induces the phosphorylation of cytosolic phospholipase A2 MAP3K14 Mitogen- kinase Activator of NFKB1 activated protein kinase kinase kinase 14 MRE11A Meiotic nuclease Exonuclease involved in DNA recombination double-strand breaks repair (S. cerevisiae) 11 homolog A NFKB1 Nuclear factor nuclear translational p105 is the precursor of the p50 of kappa light regulator subunit of the nuclear factor polypeptide NFKB, which binds to the kappa-b gene enhancer consensus sequence located in the in B-cells 1 enhancer region of genes involved (p105) in immune response and acute phase reactions; the precursor does not bind DNA itself PDCD8 Programmed enzyme, reductase The principal mitochondrial factor Cell Death 8 causing nuclear apoptosis. (apoptosis- Independent of caspase apoptosis. inducing factor) PNKP Polynucleotide phosphatase Catalyzes the 5-prime kinase 3′- phosphorylation of nucleic acids phosphatase and can have associated 3-prime phosphatase activity, predictive of an important function in DNA repair following ionizing radiation or oxidative damage PTEN Phosphatase tumor suppressor Tumor suppressor that modulates and tensin G1 cell cycle progression through homolog that negatively regulating the PI3- (mutated in kinase/Akt signaling pathway; one multiple critical target of this signaling advanced process is the cyclin-dependent cancers 1) kinase inhibitor p27 (CDKN1B). RAD52 RAD52 (S. cerevisiae) DNA binding proteinsor Involved in DNA double-stranded homolog break repair and meiotic/mitotic recombination RB1 Retinoblastoma tumor suppressor Regulator of cell growth; interacts 1 (including with E2F-like transcription factor; osteosarcoma) a nuclear phosphoprotein with DNA binding activity; interacts with histone deacetylase to repress transcription SMAC Second mitochondrial peptide Promotes caspase activation in mitochondria- cytochrome c/APAF-1/caspase 9 derived pathway of apoptosis activator of caspase TERT Telomerase transcriptase Ribonucleoprotein which in vitro reverse recognizes a single-stranded G-rich transcriptase telomere primer and adds multiple telomeric repeats to its 3-prime end by using an RNA template TNF Tumor necrosis cytokines-chemokines- Proinflammatory, TH1, mediates factor growth factors host response to bacterial stimulus, regulates cell growth & differentiation TNFRSF11A Tumor necrosis receptor Activates NFKB1; Important factor receptor regulator of interactions between T superfamily, cells and dendritic cells member 11a, activator of NFKB TNFRSF12 Tumor necrosis receptor Induces apoptosis and activates factor receptor NF-kappaB; contains a superfamily, cytoplasmic death domain and member 12 transmembrane domains (translocating chain- association membrane protein) TOSO Regulator of receptor Potent inhibitor of Fas induced Fas-induced apoptosis; expression of TOSO, apoptosis like that of FAS and FASL, increases after T-cell activation, followed by a decline and susceptibility to apoptosis; hematopoietic cells expressing TOSO resist anti-FAS-, FADD-, and TNF-induced apoptosis without increasing expression of the inhibitors of apoptosis BCL2 and BCLXL; cells expressing TOSO and activated by FAS have reduced CASP8 and increased CFLAR expression, which inhibits CASP8 processing TP53 Tumor Protein DNA binding protein- Activates expression of genes that 53 cell cycle-tumor inhibit tumor growth and/or suppressor invasion; involved in cell cycle regulation (required for growth arrest at G1); inhibits cell growth through activation of cell-cycle arrest and apoptosis TRADD TNFRSF1A- co-receptor Overexpression of TRADD leads associated via to 2 major TNF-induced responses, death domain apoptosis and activation of NF- kappa-B TRAF1 TNF receptor- co-receptor Interact with cytoplasmic domain associated of TNFR2 factor 1 TRAF2 TNF receptor- co-receptor Interact with cytoplasmic domain associated of TNFR2 factor 2 VDAC1 Voltage- membrane protein Functions as a voltage-gated pore dependent of the outer mitochondrial anion channel 1 membrane; proapoptotic proteins BAX and BAK accelerate the opening of VDAC allowing cytochrome c to enter, whereas the antiapoptotic protein BCL2L1 closes VDAC by binding directly to it XRCC5 X-ray repair helicase Functions together with the DNA complementing ligase IV-XRCC4 complex in the defective repair repair of DNA double-strand in Chinese breaks hamster cells 5

TABLE 8 Cytokine Gene Expression Panel Symbol Name Classification Description CSF3 Colony Cytokines/ AKA G-CSF; Cytokine that Stimulating Chemokines/Growth stimulates granulocyte Factor 3 Factors development (Granulocyte) IFNG Interferon, Cytokines/ Pro- and anti-inflammatoy activity; Gamma Chemokines/Growth TH1 cytokine; nonspecific Factors inflammator mediator; produced by activated T-cells. Antiproliferative effects on transformed cells. IL1A Interleukin 1, Cytokines/ Proinflammatory; constitutively Alpha Chemokines/Growth and inducibly expressed in variety Factors of cells. Generally cytosolic and released only during severe inflammatory disease IL1B Interleukin 1, Cytokines/ Proinflammatory; constitutively Beta Chemokines/Growth and inducibly expressed by many Factors cell types, secreted IL1RN Interleukin 1, Cytokines/ IL1 receptor antagonist; Receptor Chemokines/Growth Antiinflammatory; inhibits binding Antagonist Factors of IL-1 to IL-1 receptor by binding to receptor without stimulating IL- 1-like activity IL2 Interleukin 2 Cytokines/ T-cell growth factor, expressed by Chemokines/Growth activated T-cells, regulates Factors lymphocyte activation and a differentiation; inhibits apoptosis, TH1 cytokine IL4 Interleukin 4 Cytokines/ Antiinflammatory; TH2; Chemokines/Growth suppresses proinflammatory Factors cytokines, increases expression of IL-1RN, regulates lymphocyte activation IL5 Interleukin 5 Cytokines/ Eosinophil stimulatory factor; Chemokines/Growth stimulates late B cell Factors differentiation to secretion of Ig IL6 Interleukin 6 Cytokines/ AKA Interferon, Beta 2; Pro- and Chemokines/Growth anti-inflammatory activity, TH₂ Factors cytokine, regulates hematopoiesis, activation of innate response, osteoclast development; elevated in sera of patients with metastatic cancer IL10 Interleukin 10 Cytokines/ Antiinflammatory; TH₂; suppresses Chemokines/Growth production of proinflammatory Factors cytokines IL12\\BROMMAIN\ Interleukin 12 Cytokines/ Proinflammatory; mediator of VOL1\ (p40) Chemokines/Growth innate immunity, TH₁ cytokine, ALL Factors requires co-stimulation with IL-18 Primer Probe t induce IFN-γ TechSheets\Completed\IL!@ Btksht.doc IL13 Interleukin 13 Cytokines/ Inhibits inflammatory cytokine Chemokines/Growth production Factors IL15 Interleukin 15 Cytokines/ Proinflammatory; mediates T-cell Chemokines/Growth activation inhibits apoptosis, Factors synergizes with IL-2 to induce IFN-γ and TNF-α IL18 Interleukin 18 Cytokines/ Proinflammatory, TH1, innate and Chemokines/Growth acquired immunity, promotes Factors apoptosis, requires co-stimulation with IL-1 or IL-2 to induce TH1 cytokines in T- and NK-cells IL18BP IL-18 Binding Cytokines/ Implicated in inhibition of early Protein Chemokines/Growth TH1 cytokine responses Factors TGFA Transforming Transferase/Signal Proinflammatory cytokine that is Growth Factor, Transduction the primary mediator of immune Alpha response and regulation, Associated with TH1 responses, mediates host response to bacterial stimuli, regulates cell growth & differentiation; Negative regulation of insulin action TGFB1 Transforming Cytokines/ AKA DPD1, CED; Pro- and Growth Factors, Chemokines/Growth antiinflammatory activity; Anti- Beta 1 Factor apoptotic; cell-cell signaling, Can either inhibit or stimulate cell growth; Regulated by glucose in NIDDM individuals, overexpression (due to oxidative stress promotes renal cell hypertrophy leading to diabetic nephropathy) TNFSF5 Tumor Necrosis Cytokines/ Ligand for CD40; Expressed on Factor (Ligand) Chemokines/Growth the surface of T-cells; Regulates B- Superfamily, Factors cell function by engaging CD40 on Member 5 the B-cell surface TNFSF6 Tumor Necrosis Cytokines/Chemokines/ AKA FASL; Apoptosis antigen Factor (Ligand) Growth Factors ligand 1 is the ligand for FAS Superfamily, antigen; Critical in triggering Member 6 apoptosis of some types of cells such as lymphocytes; Defects in protein may be related to some cases of SLE TNFSF13B Tumor Necrosis Cytokines/ B-cell activating factor, TNF Factor (Ligand) Chemokines/Growth family Superfamily, Factors Member 13B

TABLE 9 TNF/IL1 Inhibition Gene Expression Panel HUGO Symbol Name Classification Description CD14 CD14 Antigen Cell Marker LPS receptor used as marker for monocytes GRO1 GRO1 Oncogene Cytokines/Chemokines/ AKA SCYB1, Melanoma growth Growth Factors stimulating activity, Alpha; Chemotactic for neutrophils HMOX1 Heme Oxygenase Enzyme: Redox Enzyme that cleaves heme to form (Decycling) 1 biliverdin and CO; Endotoxin inducible ICAM1 Intercellular Cell Adhesion: Matrix Endothelial cell surface molecule; Adhesion Protein Regulates cell adhesion and Molecule 1 trafficking: Up-regulated during cytokine stimulation IL1B Interleukin 1, Cytokines/Chemokines/ Pro-inflammatory; Constitutively Beta Growth Factors and inducibly expressed by many cell types; Secreted IL1RN Interleukin 1 Cytokines/Chemokines/ Anti-inflammatory; Inhibits Receptor Growth Factors binding of IL-1 to IL-1 receptor by Antagonist binding to receptor without stimulating IL-1-like activity IL10 Interleukin 10 Cytokines/Chemokines/ Anti-inflammatory; TH₂ cytokine; Growth Factors Suppresses production of pro- inflammatory cytokines MMP9 Matrix Proteinase/Proteinase AKA Gelatinase B; Degrades Metalloproteinase 9 Inhibitor extracellular matrix molecules; Secreted by IL-8 stimulated neutrophils SERPINE1 Serine (or Proteinase/Proteinase AKA Plasminogen activator Cysteine) Inhibitor inhibitor-1, PAI-1; Regulator of Inhibitor, Clade E Protease fibrinolysis (Ovalbumin), Member 1 TGFB1 Transforming Cytokines/Chemokines/ Pro- and anti-inflammatory Growth Factor, Growth Factors activity; Anti-apoptotic; Cell-cell Beta 1 signaling; Can either inhibit or stimulate cell growth TIMP1 Tissue Inhibitor Proteinase/Proteinase Irreversibly binds and inhibits of Inhibitor metalloproteinases such as Metalloproteinase 1 collagenase TNFA Tumor Necrosis Cytokines/Chemokines/ Pro-inflammatory; TH₁ cytokine; Factor, Alpha Growth Factors Mediates host response to bacterial stimulus; Regulates cell growth & differentiation

TABLE 10 Chemokine Gene Expression Panel Symbol Name Classification Description CCR1 chemokine (C-C Chemokine receptor A member of the beta chemokine motif) receptor 1 receptor family (seven transmembrane protein). Binds SCYA3/MIP-1a, SCYA5/RANTES, MCP-3, HCC- 1, 2, and 4, and MPIF-1. Plays role in dendritic cell migration to inflammation sites and recruitment of monocytes. CCR3 chemokine (C-C Chemokine receptor C-C type chemokine receptor motif) receptor 3 (Eotaxin receptor) binds to Eotaxin, Eotaxin-3, MCP-3, MCP- 4, SCYA5/RANTES and mip-1 delta thereby mediating intracellular calcium flux. Alternative co-receptor with CD4 for HIV-1 infection. Involved in recruitment of eosinophils. Primarily a Th2 cell chemokine receptor. CCR5 chemokine (C-C Chemokine receptor Member of the beta chemokine motif) receptor 5 receptor family (seven transmembrane protein). Binds to SCYA3/MIP-1a and SCYA5/RANTES. Expressed by T cells and macrophages, and is an important co-receptor for macrophage-tropic virus, including HIV, to enter host cells. Plays a role in Th1 cell migration. Defective alleles of this gene have been associated with the HIV infection resistance. CX3CR1 chemokine (C—X3—C) Chemokine receptor CX3CR1 is an HIV coreceptor as receptor 1 well as a leukocyte chemotactic/adhesion receptor for fractalkine. Natural killer cells predominantly express CX3CR1 and respond to fractalkine in both migration and adhesion. CXCR4 chemokine (C—X—C Chemokine receptor Receptor for the CXC chemokine motif), receptor SDF1. Acts as a co-receptor with 4 (fusin) CD4 for lymphocyte-tropic HIV-1 viruses. Plays role in B cell, Th2 cell and naive T cell migration. GPR9 G protein- Chemokine receptor CXC chemokine receptor binds to coupled receptor 9 SCYB10/IP-10, SCYB9/MIG, SCYB11/I-TAC. Binding of chemokines to GPR9 results in integrin activation cytoskeletal changes and chemotactic migration. Prominently expressed in in vitro cultured effector/memory T cells and plays a role in Th1 cell migration. GRO1 GRO1 oncogene Chemokine AKA SCYB1; chemotactic for (melanoma neutrophils. GRO1 is also a growth mitogenic polypeptide secreted by stimulating human melanoma cells. activity, alpha) GRO2 GRO2 oncogene Chemokine AKA MIP2, SCYB2; Macrophage (MIP-2) inflammatory protein produced by monocytes and neutrophils. Belongs to intercrine family alpha (CXC chemokine). IL8 interleukin 8 Chemokine Proinflammatory, major secondary inflammatory mediator, cell adhesion, signal transduction, cell- cell signaling, angiogenesis, synthesized by a wide variety of cell types PF4 Platelet Factor 4 Chemokine PF4 is released during platelet (SCYB4) aggregation and is chemotactic for neutrophils and monocytes. PF4's major physiologic role appears to be neutralization of heparin-like molecules on the endothelial surface of blood vessels, thereby inhibiting local antithrombin III activity and promoting coagulation. SCYA2 small inducible Chemokine Recruits monocytes to areas of cytokine A2 injury and infection. Stimulates IL- (MCP1) 4 production; implicated in diseases involving monocyte, basophil infiltration of tissue (ie.g., psoriasis, rheumatoid arthritis, atherosclerosis). SCYA3 small inducible Chemokine A “monokine” involved in the cytokine A3 acute inflammatory state through (MIP1a) the recruitment and activation of polymorphonuclear leukocytes. A major HIV-suppressive factor produced by CD8-positive T cells. SCYA5 small inducible Chemokine Binds to CCR1, CCR3, and CCR5 cytokine A5 and is a chemoattractant for blood (RANTES) monocytes, memory t helper cells and eosinophils. A major HIV- suppressive factor produced by CD8-positive T cells. SCYB10 small inducible Chemokine A CXC subfamily chemokine. cytokine Binding of SCYB10 to receptor subfamily B CXCR3/GPR9 results in (Cys-X-Cys), stimulation of monocytes, natural member 10 killer and T-cell migration, and modulation of adhesion molecule expression. SCYB10 is induced by IFNg and may be a key mediator in IFNg response. SDF1 stromal cell- Chemokine Belongs to the CXC subfamily of derived factor 1 the intercrine family, which activate leukocytes. SDF1 is the primary ligand for CXCR4, a coreceptor with CD4 for human immunodeficiency virus type 1 (HIV-1). SDF1 is a highly efficacious lymphocyte chemoattractant.

TABLE 11 Breast Cancer Gene Expression Panel Symbol Name Classification Description ACTB Actin, beta Cell Structure Actins are highly conserved proteins that are involved in cell motility, structure and integrity. ACTB is one of two non-muscle cytoskeletal actins. Site of action for cytochalasin B effects on cell motility. BCL2 B-cell membrane protein Interferes with the activation of CLL/lymphoma 2 caspases by preventing the release of cytochrome c, thus blocking apoptosis. CD19 CD19 antigen Cell Marker AKA Leu 12; B cell growth factor CD34 CD34 antigen Cell Marker AKA: hematopoietic progenitor cell antigen. Cell surface antigen selectively expressed on human hematopoietic progenitor cells. Endothelial marker. CD44 CD44 antigen Cell Marker Cell surface receptor for hyaluronate. Probably involved in matrix adhesion, lymphocyte activation and lymph node homing. DC13 DC13 protein unknown function DSG1 Desmoglein 1 membrane protein Calcium-binding transmembrane glycoprotein involved in the interaction of plaque proteins and intermediate filaments mediating cell-cell adhesion. Interact with cadherins. EDR2 Early The specific function in human Development cells has not yet been determined. Regulator 2 May be part of a complex that may regulate transcription during embryonic development. ERBB2 v-erb-b2 Oncogene Oncogene. Overexpression of erythroblastic ERBB2 confers Taxol resistance in leukemia viral breast cancers. Belongs to the EGF oncogene tyrosine kinase receptor family. homolog 2 Binds gp130 subunit of the IL6 receptor in an IL6 dependent manner. An essential component of IL-6 signalling through the MAP kinase pathway. ERBB3 v-erb-b2 Oncogene Oncogene. Overexpressed in Erythroblastic mammary tumors. Belongs to the Leukemia Viral EGF tyrosine kinase receptor Oncogene family. Activated through Homolog 3 neuregulin and ntak binding. ESR1 Estrogen Receptor/Transcription ESR1 is a ligand-activated Receptor 1 Factor transcription factor composed of several domains important for hormone binding, DNA binding, and activation of transcription. FGF18 Fibroblast Growth Factor Involved in a variety of biological Growth Factor processes, including embryonic 18 development, cell growth, morphogenesis, tissue repair, tumor growth, and invasion. FLT1 Fms-related Receptor Receptor for VEGF; involved in tyrosine kinase 1 vascular development and regulation of vascular permeability. FOS V-fos FBJ Oncogene/ Leucine zipper protein that forms murine Transcriptional Activator the transcription factor AP-1 by osteosarcoma dimerizing with JUN. Implicated viral oncogene in the processes of cell homolog proliferation, differentiation, transformation, and apoptosis. GRO1 GRO1 oncogene Chemokine/Growth Proinflammatory; chemotactic for Factor/Oncogene neutrophils. Growth regulator that modulates the expression of metalloproteinase activity. IFNG Interferon, Cytokine Pro- and antiinflammatory activity; gamma TH1 cytokine; nonspecific inflammatory mediator; produced by activated T-cells. Antiproliferative effects on transformed cells. IRF5 Interferon Transcription Factor Regulates transcription of regulatory factor 5 interferon genes through DNA sequence-specific binding. Diverse roles, include virus-mediated activation of interferon, and modulation of cell growth, differentiation, apoptosis, and immune system activity. KRT14 Keratin 14 Cytoskeleton Type I keratin, intermediate filament component; KRT14 is detected in the basal layer, with lower expression in more apical layers, and is not present in the stratum corneum. Together with KRT5 forms the cytoskeleton of epithelial cells. KRT19 Keratin 19 Cytoskeleton Type I epidermal keratin; may form intermediate filaments. Expressed often in epithelial cells in culture and in some carcinomas KRT5 Keratin 5 Cytoskeleton Coexpressed with KRT14 to form cytoskeleton of epithelial cells. KRT5 expression is a hallmark of mitotically active keratinocytes and is the primary structural component of the 10 nm intermediate filaments of the mitotic epidermal basal cells. MDM2 Mdm2, Oncogene/Transcription Inhibits p53- and p73-mediated transformed 3T3 Factor cell cycle arrest and apoptosis by cell double binding its transcriptional minute 2, p53 activation domain, resulting in binding protein tumorigenesis. Permits the nuclear export of p53 and targets it for proteasome-mediated proteolysis. MMP9 Matrix Proteinase/Proteinase Degrades extracellular matrix by metalloproteinase 9 Inhibitor cleaving types IV and V collagen. Implicated in arthritis and metastasis. MP1 Metalloprotease 1 Proteinase/Proteinase Member of the pitrilysin family. A Inhibitor metalloendoprotease. Could play a broad role in general cellular regulation. N33 Putative prostate Tumor Suppressor Integral membrane protein. cancer tumor Associated with homozygous suppressor deletion in metastatic prostate cancer. OXCT 3-oxoacid CoA Transferase OXCT catalyzes the reversible transferase transfer of coenzyme A from succinyl-CoA to acetoacetate as the first step of ketolysis (ketone body utilization) in extrahepatic tissues. PCTK1 PCTAIRE Belongs to the SER/THR family of protein kinase 1 protein kinases; CDC2/CDKX subfamily. May play a role in signal transduction cascades in terminally differentiated cells. SERPINB5 Serine proteinase Proteinase/Proteinase Protease Inhibitor; Tumor inhibitor, clade Inhibitor/Tumor suppressor, especially for B, member 5 Suppressor metastasis. Inhibits tumor invasion by inhibiting cell motility. SRP19 Signal Responsible for signal-recognition- recognition particle assembly. SRP mediates particle 19 kD the targeting of proteins to the endoplasmic reticulum. STAT1 Signal transducer DNA Binding Protein Binds to the IFN-Stimulated and activator of Response Element (ISRE) and to transcription 1, the GAS element; specifically 91 kD required for interferon signaling. STAT1 can be activated by IFN- alpha, IFN-gamma, EGF, PDGF and IL6. BRCA1-regulated genes overexpressed in breast tumorigenesis included STAT1 and JAK1. TGFB3 Transforming Cell Signalling Transmits signals through growth factor, transmembrane serine/threonine beta 3 kinases. Increased expression of TGFB3 may contribute to the growth of tumors. TLX3 T-cell leukemia, Transcription Factor Member of the homeodomain homeobox 3 family of DNA binding proteins. May be activated in T-ALL leukomogenesis. VWF Von Willebrand Coagulation Factor Multimeric plasma glycoprotein factor active in the blood coagulation system as an antihemophilic factor (VIIIC) carrier and platelet-vessel wall mediator. Secreted by endothelial cells.

TABLE 12 Infectious Disease Gene Expression Panel Symbol Name Classification Description C1QA Complement Proteinase/Proteinase Serum complement system; forms component 1, q Inhibitor C1 complex with the proenzymes subcomponent, clr and cls alpha polypeptide CASP1 Caspase 1 proteinase Activates IL1B; stimulates apoptosis CD14 CD14 antigen Cell Marker LPS receptor used as marker for monocytes CSF2 Granulocyte- cytokines-chemokines- AKA GM-CSF; Hematopoietic monocyte colony growth factors growth factor; stimulates growth stimulating factor and differentiation of hematopoietic precursor cells from various lineages, including granulocytes, macrophages, eosinophils, and erythrocytes EGR1 Early growth cell signaling and master inflammatory switch for response-1 activation ischemia-related responses including chemokine sysntheis, adhesion moelcules and macrophage differentiation F3 F3 Enzyme/Redox AKA thromboplastin, Coagulation Factor 3; cell surface glycoprotein responsible for coagulation catalysis GRO2 GRO2 oncogene cytokines-chemokines- AKA MIP2, SCYB2; Macrophage growth factors inflammatory protein produced by monocytes and neutrophils HMOX1 Heme oxygenase Enzyme/Redox Endotoxin inducible (decycling) 1 HSPA1A Heat shock Cell Signaling and heat shock protein 70 kDa protein 70 activation ICAM1 Intercellular Cell Adhesion/Matrix Endothelial cell surface molecule; adhesion Protein regulates cell adhesion and molecule 1 trafficking, upregulated during cytokine stimulation IFI16 gamma cell signaling and Transcriptional repressor interferon activation inducible protein 16 IFNG Interferon cytokines-chemokines- Pro- and antiinflammatory activity, gamma growth factors TH1 cytokine, nonspecific inflammatory mediator, produced by activated T-cells IL10 Interleukin 10 cytokines-chemokines- Antiinflammatory; TH2; growth factors suppresses production of proinflammatory cytokines IL12B Interleukin 12 cytokines-chemokines- Proinflammatory; mediator of p40 growth factors innate immunity, TH1 cytokine, requires co-stimulation with IL-18 to induce IFN-g IL13 Interleukin 13 cytokines-chemokines- Inhibits inflammatory cytokine growth factors production IL18 Interleukin 18 cytokines-chemokines- Proinflammatory, TH1, innate and growth factors aquired immunity, promotes apoptosis, requires co-stimulation with IL-1 or IL-2 to induce TH1 cytokines in T- and NK-cells IL18BP IL-18 Binding cytokines-chemokines- Implicated in inhibition of early Protein growth factors TH1 cytokine responses IL1A Interleukin 1, cytokines-chemokines- Proinflammatory; constitutively alpha growth factors and inducibly expressed in variety of cells. Generally cytosolic and released only during severe inflammatory disease IL1B Interleukin 1, cytokines-chemokines- Proinflammatory; constitutively beta growth factors and inducibly expressed by many cell types, secreted IL1R1 interleukin 1 receptor AKA: CD12 or IL1R1RA receptor, type I IL1RN Interleukin 1 cytokines-chemokines- IL1 receptor antagonist; receptor growth factors Antiinflammatory; inhibits binding antagonist of IL-1 to IL-1 receptor by binding to receptor without stimulating IL- 1-like activity IL2 Interleukin 2 cytokines-chemokines- T-cell growth factor, expressed by growth factors activated T-cells, regulates lymphocyte activation and differentiation; inhibits apoptosis, TH1 cytokine IL4 Interleukin 4 cytokines-chemokines- Antiinflammatory; TH2; growth factors suppresses proinflammatory cytokines, increases expression of IL-1RN, regulates lymphocyte activation IL6 Interleukin 6 cytokines-chemokines- Pro- and antiinflammatory activity, (interferon, beta growth factors TH2 cytokine, regulates 2) hemotopoietic system and activation of innate response IL8 Interleukin 8 cytokines-chemokines- Proinflammatory, major secondary growth factors inflammatory mediator, cell adhesion, signal transduction, cell- cell signaling, angiogenesis, synthesized by a wide variety of cell types MMP3 Matrix Proteinase/Proteinase AKA stromelysin; degrades metalloproteinase 3 Inhibitor fibronectin, laminin and gelatin MMP9 Matrix Proteinase/Proteinase AKA gelatinase B; degrades metalloproteinase 9 Inhibitor extracellular matrix molecules, secreted by IL-8-stimulated neutrophils PLA2G7 Phospholipase Enzyme/Redox Platelet activating factor A2, group VII (platelet activating factor acetylhydrolase, plasma) PLAU Plasminogen Proteinase/Proteinase AKA uPA; cleaves plasminogen to activator, Inhibitor plasmin (a protease responsible for urokinase nonspecific extracellular matrix degradation) SERPINE1 Serine (or Proteinase/Proteinase Plasminogen activator inhibitor-1/ cysteine) Inhibitor PAI-1 protease inhibitor, clade B (ovalbumin), member 1 SOD2 superoxide Oxidoreductase Enzyme that scavenges and dismutase 2, destroys free radicals within mitochondrial mitochondria TACI Tumor necrosis cytokines-chemokines- T cell activating factor and calcium factor receptor growth factors cyclophilin modulator superfamily, member 13b TIMP1 tissue inhibitor of Proteinase/Proteinase Irreversibly binds and inhibits metalloproteinase 1 Inhibitor metalloproteinases, such as collagenase TLR2 toll-like receptor 2 cell signaling and mediator of petidoglycan and activation lipotechoic acid induced signalling TLR4 toll-like receptor 4 cell signaling and mediator of LPS induced signalling activation TNF Tumor necrosis cytokines-chemokines- Proinflammatory, TH1, mediates factor, alpha growth factors host response to bacterial stimulus, regulates cell growth & differentiation TNFSF13B Tumor necrosis cytokines-chemokines- B cell activating factor, TNF factor (ligand) growth factors family superfamily, member 13b TNFSF5 Tumor necrosis cytokines-chemokines- ligand for CD40; expressed on the factor (ligand) growth factor surface of T cells. It regulates B superfamily, cell function by engaging CD40 on member 5 the B cell surface TNFSF6 Tumor necrosis cytokines-chemokines- AKA FasL; Ligand for FAS factor (ligand) growth factors antigen; transduces apoptotic superfamily, signals into cells member 6 VEGF vascular cytokines-chemokines- Producted by monocytes endothelial growth factors growth factor IL5 Interleukin 5 Cytokines-chemokines- Eosinophil stimulatory factor; growth factors stimulates late B cell differentiation to secretion of Ig IFNA2 Interferon alpha 2 Cytokines-chemokines- interferon produced by growth factors macrophages with antiviral effects TREM1 TREM-1 Triggering Receptor Receptor/Cell Signaling and Expressed on Myeloid Activation Cells 1 SCYB10 small inducible Chemokine A CXC subfamily chemokine. cytokine Binding of SCYB10 to receptor subfamily B CXCR3/GPR9 results in (Cys-X-Cys), stimulation of monocytes, natural member 10 killer and T-cell migration, and modulation of adhesion molecule expression. SCYB10 is Induced by IFNg and may be a key mediator in IFNg response. CCR1 Chemokine (C-C Chemokine receptor A member of the beta chemokine motif) receptor 1 receptor family (seven transmembrane protein). Binds SCYA3/MIP-1a, SCYA5/RANTES, MCP-3, HCC- 1, 2, and 4, and MPIF-1. Plays role in dendritic cell migration to inflammation sites and recruitment of monocytes. CCR3 Chemokine (C-C Chemokine receptor C-C type chemokine receptor motif) receptor 3 (Eotaxin receptor) binds to Eotaxin, Eotaxin-3, MCP-3, MCP- 4, SCYA5/RANTES and mip-1 delta thereby mediating intracellular calcium flux. Alternative co-receptor with CD4 for HIV-1 infection. Involved in recruitment of eosinophils. Primarily a Th2 cell chemokine receptor. SCYA3 Small inducile Chemokine A “monokine” involved in the cytokine A3 acute inflammatory state through (MIP1a) the recruitment and activation of polymorphonuclear leukocytes. A major HIV-suppressive factor produced b CD8-positive T cells. CX3CR1 Chemokine (C—X3—C) Chemokine receptor CX3CR1 is an HIV coreceptor as receptor 1 well as a leukocyte chemotactic/adhesion receptor for fractalkine. Natural killer cells predominantly express CX3CR1 and respond to fractalkine in both migration and adhesion. 

The invention claimed is:
 1. A method of evaluating the efficacy of a therapeutic agent on an inflammatory condition, the method comprising: a) producing a first index for a sample from a subject, the sample providing a source of RNAs comprising: i) quantitatively measuring the amount of RNA from the sample from the subject by amplification, wherein a panel of constituents is selected so that measurement conditions of the constituents enables evaluation of said inflammatory condition and wherein the measures of all constituents in the panel form a first profile data set, wherein said amplification for each constituent is under conditions that are (1) within a degree of repeatability of better than five percent; and (2) the efficiencies of amplification are within two percent, ii) inserting the values from a first profile data set into an index function derived using latent class modeling, thereby providing a single-valued measure of the inflammatory condition so as to produce an index pertinent to the inflammatory condition of the subject, wherein the first profile data set is derived from quantitatively measuring the amount of RNA of all constituents in said panel from a sample of a plurality of subjects of a relevant population and which measurements form a normative baseline profile data set; iii) inserting the values from the normative profile data set into the index function, thereby providing a single-valued measure of the inflammatory condition so as to produce an index pertinent to the inflammatory condition of the relevant population, iv) producing an index of the subject; v) normalizing the index of the subject with the index of the relevant population to provide the first index; and (b) evaluating the efficacy of the agent based on a value of the first index prior to treatment and comparing to the value of the first index after treatment, wherein the first index is greater than 1 prior to treatment and the first index after treatment is less that 1 when treatment is efficacious.
 2. The method of claim 1, wherein the agent is selected from the group consisting of an anti-inflammatory steroid compound, non-steroidal anti-inflammatory drug and antibiotic.
 3. The method of claim 1, wherein the inflammatory condition is caused by, is a result of, or is exacerbated by, an infection.
 4. The method of claim 1, wherein treatment of the inflammatory condition is based on the prediction of efficacy of the agent.
 5. The method of claim 2, wherein the anti-inflammatory steroid compound is solumedrol, prednisone, or dexamethasone.
 6. The method of claim 2, wherein the non-steroidal anti-inflammatory drug is ibuprofen.
 7. The method of claim 2, wherein the antibiotic is polymyxin B.
 8. The method of claim 2, wherein the anti-inflammatory steroid compound is solumedrol, prednisone, or dexamethasone.
 9. The method of claim 1, wherein the panel of constituents comprises IL1A, 1L1B, TNFA, IFNG and IL10.
 10. The method of claim 9, wherein the panel further comprises B7, TACI, PLA2G7 and C1QA.
 11. The method of claim 9, wherein the panel further comprises GRO1 and GRO2.
 12. The method of claim 9, wherein the panel further comprises B7, TACI, PLA2G7, C1QA, GRO1 and GRO2. 